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4fba1fe79a ... dag-lattic

Author SHA1 Message Date
Danila Fedorin
299938d97e Add decidability proofs for properties 
Signed-off-by: Danila Fedorin <danila.fedorin@gmail.com>
 2025-12-07 22:25:47 -08:00
Danila Fedorin
927030c337 Prove that having a top and bottom element is decidable 
Signed-off-by: Danila Fedorin <danila.fedorin@gmail.com>
 2025-12-07 19:28:56 -08:00
Danila Fedorin
ef3c351bb0 Add some utility proofs about uniqueness etc. 
Signed-off-by: Danila Fedorin <danila.fedorin@gmail.com>
 2025-12-07 19:28:27 -08:00
Danila Fedorin
84c4ea6936 Prove final postulate about cycles in graphs 
Signed-off-by: Danila Fedorin <danila.fedorin@gmail.com>
 2025-11-29 22:46:49 -08:00
Danila Fedorin
a277c8f969 Prove walk splitting 
Signed-off-by: Danila Fedorin <danila.fedorin@gmail.com>
 2025-11-29 21:34:39 -08:00
Danila Fedorin
d1700f23fa Add some helpers 
Signed-off-by: Danila Fedorin <danila.fedorin@gmail.com>
 2025-11-29 13:24:27 -08:00
Danila Fedorin
eb2d64f3b5 Properly state all-paths property using simple walks 
Signed-off-by: Danila Fedorin <danila.fedorin@gmail.com>
 2025-11-28 21:31:54 -08:00
Danila Fedorin
14214ab5e7 Reorder definitions to be in the order the graph is built up 
Signed-off-by: Danila Fedorin <danila.fedorin@gmail.com>
 2025-11-28 17:09:57 -08:00
Danila Fedorin
baece236d3 Re-define 'interior' 
Signed-off-by: Danila Fedorin <danila.fedorin@gmail.com>
 2025-11-28 17:09:14 -08:00
Danila Fedorin
6f642d85e0 Put self-paths into the adjacency graph 
Signed-off-by: Danila Fedorin <danila.fedorin@gmail.com>
 2025-11-28 17:08:56 -08:00
Danila Fedorin
25fa0140f0 Switch to a path definition that allows trivial self-loops 
Signed-off-by: Danila Fedorin <danila.fedorin@gmail.com>
 2025-11-28 16:30:10 -08:00
Danila Fedorin
27621992ad Rename a helper 
Signed-off-by: Danila Fedorin <danila.fedorin@gmail.com>
 2025-11-28 16:25:46 -08:00
Danila Fedorin
e409cceae5 Start on an initial implementation of DAG-based builder 
Signed-off-by: Danila Fedorin <danila.fedorin@gmail.com>
 2025-11-28 16:24:48 -08:00
Danila Fedorin
8cb082e3c5 Delete original builder (lol) 
Signed-off-by: Danila Fedorin <danila.fedorin@gmail.com>
 2025-11-28 16:24:29 -08:00
Danila Fedorin
c199e9616f Factor some code out into Utils 
Signed-off-by: Danila Fedorin <danila.fedorin@gmail.com>
 2025-11-28 16:22:17 -08:00
Danila Fedorin
f5457d8841 Move proof of least element into FiniteHeightLattice 
Signed-off-by: Danila Fedorin <danila.fedorin@gmail.com>
 2025-07-26 13:16:22 +02:00
Danila Fedorin
d99d4a2893 [WIP] Demonstrate partial lattice construction 
Signed-off-by: Danila Fedorin <danila.fedorin@gmail.com>
 2025-07-25 19:51:27 +02:00
Danila Fedorin
fbb98de40f Prove the other absorption law 
Signed-off-by: Danila Fedorin <danila.fedorin@gmail.com>
 2025-07-25 19:26:03 +02:00
Danila Fedorin
706b593d1d Write a lemma to wrangle PartialAbsorb proofs 
Signed-off-by: Danila Fedorin <danila.fedorin@gmail.com>
 2025-07-25 19:14:49 +02:00
Danila Fedorin
45606679f5 Prove one of the absorption laws 
Signed-off-by: Danila Fedorin <danila.fedorin@gmail.com>
 2025-07-25 18:32:23 +02:00
Danila Fedorin
7e099a2561 Delete debugging code 
Signed-off-by: Danila Fedorin <danila.fedorin@gmail.com>
 2025-07-25 17:18:31 +02:00
Danila Fedorin
2808759338 Add instances of semilattice proofs 
Signed-off-by: Danila Fedorin <danila.fedorin@gmail.com>
 2025-07-25 17:18:19 +02:00
Danila Fedorin
42bb8f8792 Extend laws on Path' to Path versions 
Signed-off-by: Danila Fedorin <danila.fedorin@gmail.com>
 2025-07-25 17:17:59 +02:00
Danila Fedorin
05e693594d Prove idempotence of meet and join 
Signed-off-by: Danila Fedorin <danila.fedorin@gmail.com>
 2025-07-25 17:17:25 +02:00
Danila Fedorin
90e0046707 Prove missing congruence law 
Signed-off-by: Danila Fedorin <danila.fedorin@gmail.com>
 2025-07-25 17:17:01 +02:00
Danila Fedorin
13eee93255 Remove whitespace errors 
Signed-off-by: Danila Fedorin <danila.fedorin@gmail.com>
 2025-07-25 15:26:41 +02:00
Danila Fedorin
6243326665 Prove associativity of meet 
Signed-off-by: Danila Fedorin <danila.fedorin@gmail.com>
 2025-07-25 15:21:59 +02:00
Danila Fedorin
7b2114cd0f Use a convenience function for creating the "greatest path" 
Signed-off-by: Danila Fedorin <danila.fedorin@gmail.com>
 2025-07-25 15:21:43 +02:00
Danila Fedorin
36ae125e1e Prove associativity 
Signed-off-by: Danila Fedorin <danila.fedorin@gmail.com>
 2025-07-22 18:05:08 +02:00
Danila Fedorin
6055a79e6a Prove a side lemma about nothing/just 
Signed-off-by: Danila Fedorin <danila.fedorin@gmail.com>
 2025-07-22 18:04:53 +02:00
Danila Fedorin
01f7f678d3 Prove congruence of various operations 
Signed-off-by: Danila Fedorin <danila.fedorin@gmail.com>
 2025-07-22 18:02:45 +02:00
Danila Fedorin
14f1494fc3 Provide a definition of partial congruence 
Signed-off-by: Danila Fedorin <danila.fedorin@gmail.com>
 2025-07-22 18:01:48 +02:00
Danila Fedorin
d3bac2fe60 Switch to representing least/greatest with absorption 
It's more convenient this way to require non-partiality.

Signed-off-by: Danila Fedorin <danila.fedorin@gmail.com>
 2025-07-22 17:59:54 +02:00
Danila Fedorin
5705f256fd Prove some quasi-homomorphism properties 
Signed-off-by: Danila Fedorin <danila.fedorin@gmail.com>
 2025-07-11 15:49:56 +02:00
Danila Fedorin
d59ae90cef Lock down more equivalence relation proofs 
Signed-off-by: Danila Fedorin <danila.fedorin@gmail.com>
 2025-07-11 15:46:18 +02:00
Danila Fedorin
c1c34c69a5 Strengthen absorption laws 
If x \/ y is defined, x /\ (x \/ y) has to be defined,
too. Previously, we stated them in terms of
"if x /\ (x \/ y) is defined", which is not right.

Signed-off-by: Danila Fedorin <danila.fedorin@gmail.com>
 2025-07-11 15:44:29 +02:00
Danila Fedorin
d2faada90a Add a left and right version of identity 
Signed-off-by: Danila Fedorin <danila.fedorin@gmail.com>
 2025-07-11 15:43:27 +02:00
Danila Fedorin
7fdbf0397d Prove idempotence of value combining 
Signed-off-by: Danila Fedorin <danila.fedorin@gmail.com>
 2025-07-05 16:57:24 -07:00
Danila Fedorin
fdef8c0a60 Prove commutativity and associativity of value joining 
Signed-off-by: Danila Fedorin <danila.fedorin@gmail.com>
 2025-07-05 16:49:38 -07:00
Danila Fedorin
c48bd0272e Define "less than or equal" for partial lattices and prove some properties 
Signed-off-by: Danila Fedorin <danila.fedorin@gmail.com>
 2025-07-05 14:53:00 -07:00
Danila Fedorin
d251915772 Show that lifted equality preserves equivalences 
Signed-off-by: Danila Fedorin <danila.fedorin@gmail.com>
 2025-07-05 14:52:40 -07:00
Danila Fedorin
da6e82d04b Add helper definitions for partial commutativity, associativity, reflexivity 
Signed-off-by: Danila Fedorin <danila.fedorin@gmail.com>
 2025-07-02 15:11:12 -05:00
Danila Fedorin
dd101c6e9b Start working on a general lattice builder framework 2025-06-29 10:35:37 -07:00
Danila Fedorin
a611dd0f31 Add 'ExtendBelow' lattice, which adds new bottom to lattices 
Signed-off-by: Danila Fedorin <danila.fedorin@gmail.com>
 2025-04-20 19:13:07 -07:00
Danila Fedorin
33cc0f9fe9 Implement constant analysis 
Signed-off-by: Danila Fedorin <danila.fedorin@gmail.com>
 2025-01-05 19:39:12 -08:00
Danila Fedorin
9f2790c500 Actually force proof of 'analyze-correct' 
Signed-off-by: Danila Fedorin <danila.fedorin@gmail.com>
 2025-01-05 19:39:12 -08:00
Danila Fedorin
105321971f Slightly help along implicit inference by moving binary less-than 
Signed-off-by: Danila Fedorin <danila.fedorin@gmail.com>
 2025-01-05 19:39:12 -08:00
Danila Fedorin
236c92a5ef Add definitions about monotonicity to Lattice 
Signed-off-by: Danila Fedorin <danila.fedorin@gmail.com>
 2025-01-05 19:39:12 -08:00
Danila Fedorin
ca375976b7 Re-export members of isLattice together with the record where needed 
Signed-off-by: Danila Fedorin <danila.fedorin@gmail.com>
 2025-01-04 22:43:13 -08:00
Danila Fedorin
c0238fea25 Clean up how proofs of fixed height are imported 
Signed-off-by: Danila Fedorin <danila.fedorin@gmail.com>
 2025-01-04 22:34:49 -08:00
Danila Fedorin
1432dfa669 Clean up FiniteMap module structure a bit 
Signed-off-by: Danila Fedorin <danila.fedorin@gmail.com>
 2025-01-04 22:28:47 -08:00
Danila Fedorin
ffe9d193d9 Parameterize FiniteMap by its keys right away 
Signed-off-by: Danila Fedorin <danila.fedorin@gmail.com>
 2025-01-04 22:19:02 -08:00
Danila Fedorin
cf824dc744 Switch product to using instances 
Signed-off-by: Danila Fedorin <danila.fedorin@gmail.com>
 2025-01-04 21:33:59 -08:00
Danila Fedorin
70847d51db Swich AboveBelow to using instances 
Signed-off-by: Danila Fedorin <danila.fedorin@gmail.com>
 2025-01-04 21:23:07 -08:00
Danila Fedorin
d96eb97b69 Switch maps (and consequently most of the code) to using instances 
Signed-off-by: Danila Fedorin <danila.fedorin@gmail.com>
 2025-01-04 21:16:22 -08:00
Danila Fedorin
d90b544436 Use binary operator for decidable equality consistently 
Signed-off-by: Danila Fedorin <danila.fedorin@gmail.com>
 2025-01-04 19:08:28 -08:00
Danila Fedorin
b0488c9cc6 Make 'IsDecidable' into a record to aid instance search 
Signed-off-by: Danila Fedorin <danila.fedorin@gmail.com>
 2025-01-04 18:58:56 -08:00
Danila Fedorin
8abf6f8670 Make 'isLattice' for simple types be an instance 
Signed-off-by: Danila Fedorin <danila.fedorin@gmail.com>
 2025-01-04 17:27:38 -08:00
Danila Fedorin
4da9b6d3cd Fuse 'FiniteMap' and 'FiniteValueMap' 
Signed-off-by: Danila Fedorin <danila.fedorin@gmail.com>
 2024-12-31 19:21:23 -08:00
Danila Fedorin
c2c04e3ecd Rewrite Forward analysis to use statement-based evaluators. 
To keep old (expression-based) analyses working, switch to using
instance search and provide "adapters" that auto-construct statement
analyzers from expression analyzers.

Signed-off-by: Danila Fedorin <danila.fedorin@gmail.com>
 2024-12-31 17:31:01 -08:00
Danila Fedorin
f01df5af4b Slightly tweak module style in Forward.agda 
Signed-off-by: Danila Fedorin <danila.fedorin@gmail.com>
 2024-12-31 12:55:29 -08:00
Danila Fedorin
b28994e1d2 Tighten exported definitions in Forward.agda 
Signed-off-by: Danila Fedorin <danila.fedorin@gmail.com>
 2024-12-31 00:29:39 -08:00
Danila Fedorin
10332351ea Use instance search to avoid multiply-nested modules 
Signed-off-by: Danila Fedorin <danila.fedorin@gmail.com>
 2024-12-31 00:21:10 -08:00
Danila Fedorin
9131214880 Slightly clean up import for in-dec for Graph edges 2024-11-16 15:15:42 -08:00
26 changed files with 2292 additions and 1278 deletions
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Analysis/Constant.agda Normal file
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module Analysis.Constant where
open import Data.Integer as Int using (; +_; -[1+_]; _≟_)
open import Data.Integer.Show as IntShow using ()
open import Data.Nat as Nat using (; suc; zero)
open import Data.Product using (Σ; proj₁; proj₂; _,_)
open import Data.Sum using (inj₁; inj₂)
open import Data.Empty using (⊥; ⊥-elim)
open import Data.Unit using (; tt)
open import Data.List.Membership.Propositional as MemProp using () renaming (_∈_ to _∈ˡ_)
open import Relation.Binary.PropositionalEquality using (_≡_; refl; sym; trans; subst)
open import Relation.Nullary using (¬_; yes; no)
open import Equivalence
open import Language
open import Lattice
open import Showable using (Showable; show)
open import Utils using (_⇒_; _∧_; __)
open import Analysis.Utils using (eval-combine₂)
import Analysis.Forward
instance
showable : Showable
showable = record
{ show = IntShow.show
}
instance
≡-equiv : IsEquivalence _≡_
≡-equiv = record
{ ≈-refl = refl
; ≈-sym = sym
; ≈-trans = trans
}
≡-Decidable- : IsDecidable {_} {} _≡_
≡-Decidable- = record { R-dec = _≟_ }
-- embelish '' with a top and bottom element.
open import Lattice.AboveBelow _ as AB
using ()
renaming
( AboveBelow to ConstLattice
; ≈-dec to ≈ᶜ-dec
; to ⊥ᶜ
; to ⊤ᶜ
; [_] to [_]ᶜ
; _≈_ to _≈ᶜ_
; ≈-⊥-⊥ to ≈ᶜ-⊥ᶜ-⊥ᶜ
; ≈-- to ≈ᶜ-⊤ᶜ-⊤ᶜ
; ≈-lift to ≈ᶜ-lift
; ≈-refl to ≈ᶜ-refl
)
-- '''s structure is not finite, so just use a 'plain' above-below Lattice.
open AB.Plain (+ 0) using ()
renaming
( isLattice to isLatticeᶜ
; isFiniteHeightLattice to isFiniteHeightLatticeᵍ
; _≼_ to _≼ᶜ_
; _⊔_ to _⊔ᶜ_
; _⊓_ to _⊓ᶜ_
; ≼-trans to ≼ᶜ-trans
; ≼-refl to ≼ᶜ-refl
)
plus : ConstLattice ConstLattice ConstLattice
plus ⊥ᶜ _ = ⊥ᶜ
plus _ ⊥ᶜ = ⊥ᶜ
plus ⊤ᶜ _ = ⊤ᶜ
plus _ ⊤ᶜ = ⊤ᶜ
plus [ z₁ ]ᶜ [ z₂ ]ᶜ = [ z₁ Int.+ z₂ ]ᶜ
-- this is incredibly tedious: 125 cases per monotonicity proof, and tactics
-- are hard. postulate for now.
postulate plus-Monoˡ : (s₂ : ConstLattice) Monotonic _≼ᶜ_ _≼ᶜ_ (λ s₁ plus s₁ s₂)
postulate plus-Monoʳ : (s₁ : ConstLattice) Monotonic _≼ᶜ_ _≼ᶜ_ (plus s₁)
plus-Mono₂ : Monotonic₂ _≼ᶜ_ _≼ᶜ_ _≼ᶜ_ plus
plus-Mono₂ = (plus-Monoˡ , plus-Monoʳ)
minus : ConstLattice ConstLattice ConstLattice
minus ⊥ᶜ _ = ⊥ᶜ
minus _ ⊥ᶜ = ⊥ᶜ
minus ⊤ᶜ _ = ⊤ᶜ
minus _ ⊤ᶜ = ⊤ᶜ
minus [ z₁ ]ᶜ [ z₂ ]ᶜ = [ z₁ Int.- z₂ ]ᶜ
postulate minus-Monoˡ : (s₂ : ConstLattice) Monotonic _≼ᶜ_ _≼ᶜ_ (λ s₁ minus s₁ s₂)
postulate minus-Monoʳ : (s₁ : ConstLattice) Monotonic _≼ᶜ_ _≼ᶜ_ (minus s₁)
minus-Mono₂ : Monotonic₂ _≼ᶜ_ _≼ᶜ_ _≼ᶜ_ minus
minus-Mono₂ = (minus-Monoˡ , minus-Monoʳ)
⟦_⟧ᶜ : ConstLattice Value Set
⟦_⟧ᶜ ⊥ᶜ _ =
⟦_⟧ᶜ ⊤ᶜ _ =
⟦_⟧ᶜ [ z ]ᶜ v = v ↑ᶻ z
⟦⟧ᶜ-respects-≈ᶜ : {s₁ s₂ : ConstLattice} s₁ ≈ᶜ s₂ s₁ ⟧ᶜ s₂ ⟧ᶜ
⟦⟧ᶜ-respects-≈ᶜ ≈ᶜ-⊥ᶜ-⊥ᶜ v bot = bot
⟦⟧ᶜ-respects-≈ᶜ ≈ᶜ-⊤ᶜ-⊤ᶜ v top = top
⟦⟧ᶜ-respects-≈ᶜ (≈ᶜ-lift { z } { z } refl) v proof = proof
⟦⟧ᶜ-⊔ᶜ- : {s₁ s₂ : ConstLattice} ( s₁ ⟧ᶜ s₂ ⟧ᶜ) s₁ ⊔ᶜ s₂ ⟧ᶜ
⟦⟧ᶜ-⊔ᶜ- {⊥ᶜ} x (inj₂ px₂) = px₂
⟦⟧ᶜ-⊔ᶜ- {⊤ᶜ} x _ = tt
⟦⟧ᶜ-⊔ᶜ- {[ s₁ ]ᶜ} {[ s₂ ]ᶜ} x px
with s₁ s₂
... | no _ = tt
... | yes refl
with px
... | inj₁ px₁ = px₁
... | inj₂ px₂ = px₂
⟦⟧ᶜ-⊔ᶜ- {[ s₁ ]ᶜ} {⊥ᶜ} x (inj₁ px₁) = px₁
⟦⟧ᶜ-⊔ᶜ- {[ s₁ ]ᶜ} {⊤ᶜ} x _ = tt
s₁≢s₂⇒¬s₁∧s₂ : {z₁ z₂ : } ¬ z₁ z₂ {v} ¬ (( [ z₁ ]ᶜ ⟧ᶜ [ z₂ ]ᶜ ⟧ᶜ) v)
s₁≢s₂⇒¬s₁∧s₂ { z₁ } { z₂ } z₁≢z₂ {v} (v≡z₁ , v≡z₂)
with refl trans (sym v≡z₁) v≡z₂ = z₁≢z₂ refl
⟦⟧ᶜ-⊓ᶜ-∧ : {s₁ s₂ : ConstLattice} ( s₁ ⟧ᶜ s₂ ⟧ᶜ) s₁ ⊓ᶜ s₂ ⟧ᶜ
⟦⟧ᶜ-⊓ᶜ-∧ {⊥ᶜ} x (bot , _) = bot
⟦⟧ᶜ-⊓ᶜ-∧ {⊤ᶜ} x (_ , px₂) = px₂
⟦⟧ᶜ-⊓ᶜ-∧ {[ s₁ ]ᶜ} {[ s₂ ]ᶜ} x (px₁ , px₂)
with s₁ s₂
... | no s₁≢s₂ = s₁≢s₂⇒¬s₁∧s₂ s₁≢s₂ (px₁ , px₂)
... | yes refl = px₁
⟦⟧ᶜ-⊓ᶜ-∧ {[ g₁ ]ᶜ} {⊥ᶜ} x (_ , bot) = bot
⟦⟧ᶜ-⊓ᶜ-∧ {[ g₁ ]ᶜ} {⊤ᶜ} x (px₁ , _) = px₁
instance
latticeInterpretationᶜ : LatticeInterpretation isLatticeᶜ
latticeInterpretationᶜ = record
{ ⟦_⟧ = ⟦_⟧ᶜ
; ⟦⟧-respects-≈ = ⟦⟧ᶜ-respects-≈ᶜ
; ⟦⟧-⊔- = ⟦⟧ᶜ-⊔ᶜ-
; ⟦⟧-⊓-∧ = ⟦⟧ᶜ-⊓ᶜ-∧
}
module WithProg (prog : Program) where
open Program prog
open import Analysis.Forward.Lattices ConstLattice prog
open import Analysis.Forward.Evaluation ConstLattice prog
open import Analysis.Forward.Adapters ConstLattice prog
eval : (e : Expr) VariableValues ConstLattice
eval (e₁ + e₂) vs = plus (eval e₁ vs) (eval e₂ vs)
eval (e₁ - e₂) vs = minus (eval e₁ vs) (eval e₂ vs)
eval (` k) vs
with ∈k-decᵛ k (proj₁ (proj₁ vs))
... | yes k∈vs = proj₁ (locateᵛ {k} {vs} k∈vs)
... | no _ = ⊤ᶜ
eval (# n) _ = [ + n ]ᶜ
eval-Monoʳ : (e : Expr) Monotonic _≼ᵛ_ _≼ᶜ_ (eval e)
eval-Monoʳ (e₁ + e₂) {vs₁} {vs₂} vs₁≼vs₂ =
eval-combine₂ (λ {x} {y} {z} ≼ᶜ-trans {x} {y} {z})
plus plus-Mono₂ {o₁ = eval e₁ vs₁}
(eval-Monoʳ e₁ vs₁≼vs₂) (eval-Monoʳ e₂ vs₁≼vs₂)
eval-Monoʳ (e₁ - e₂) {vs₁} {vs₂} vs₁≼vs₂ =
eval-combine₂ (λ {x} {y} {z} ≼ᶜ-trans {x} {y} {z})
minus minus-Mono₂ {o₁ = eval e₁ vs₁}
(eval-Monoʳ e₁ vs₁≼vs₂) (eval-Monoʳ e₂ vs₁≼vs₂)
eval-Monoʳ (` k) {vs₁@((kvs₁ , _) , _)} {vs₂@((kvs₂ , _), _)} vs₁≼vs₂
with ∈k-decᵛ k kvs₁ | ∈k-decᵛ k kvs₂
... | yes k∈kvs₁ | yes k∈kvs₂ =
let
(v₁ , k,v₁∈vs₁) = locateᵛ {k} {vs₁} k∈kvs₁
(v₂ , k,v₂∈vs₂) = locateᵛ {k} {vs₂} k∈kvs₂
in
m₁≼m₂⇒m₁[k]ᵛ≼m₂[k]ᵛ vs₁ vs₂ vs₁≼vs₂ k,v₁∈vs₁ k,v₂∈vs₂
... | yes k∈kvs₁ | no k∉kvs₂ = ⊥-elim (k∉kvs₂ (subst (λ l k ∈ˡ l) (all-equal-keysᵛ vs₁ vs₂) k∈kvs₁))
... | no k∉kvs₁ | yes k∈kvs₂ = ⊥-elim (k∉kvs₁ (subst (λ l k ∈ˡ l) (all-equal-keysᵛ vs₂ vs₁) k∈kvs₂))
... | no k∉kvs₁ | no k∉kvs₂ = IsLattice.≈-refl isLatticeᶜ
eval-Monoʳ (# n) _ = ≼ᶜ-refl ([ + n ]ᶜ)
instance
ConstEval : ExprEvaluator
ConstEval = record { eval = eval; eval-Monoʳ = eval-Monoʳ }
-- For debugging purposes, print out the result.
output = show (Analysis.Forward.WithProg.result ConstLattice prog)
-- This should have fewer cases -- the same number as the actual 'plus' above.
-- But agda only simplifies on first argument, apparently, so we are stuck
-- listing them all.
plus-valid : {g₁ g₂} {z₁ z₂} g₁ ⟧ᶜ (↑ᶻ z₁) g₂ ⟧ᶜ (↑ᶻ z₂) plus g₁ g₂ ⟧ᶜ (↑ᶻ (z₁ Int.+ z₂))
plus-valid {⊥ᶜ} {_} _ =
plus-valid {[ z ]ᶜ} {⊥ᶜ} _ =
plus-valid {⊤ᶜ} {⊥ᶜ} _ =
plus-valid {⊤ᶜ} {[ z ]ᶜ} _ _ = tt
plus-valid {⊤ᶜ} {⊤ᶜ} _ _ = tt
plus-valid {[ z₁ ]ᶜ} {[ z₂ ]ᶜ} refl refl = refl
plus-valid {[ z ]ᶜ} {⊤ᶜ} _ _ = tt
--
-- Same for this one. It should be easier, but Agda won't simplify.
minus-valid : {g₁ g₂} {z₁ z₂} g₁ ⟧ᶜ (↑ᶻ z₁) g₂ ⟧ᶜ (↑ᶻ z₂) minus g₁ g₂ ⟧ᶜ (↑ᶻ (z₁ Int.- z₂))
minus-valid {⊥ᶜ} {_} _ =
minus-valid {[ z ]ᶜ} {⊥ᶜ} _ =
minus-valid {⊤ᶜ} {⊥ᶜ} _ =
minus-valid {⊤ᶜ} {[ z ]ᶜ} _ _ = tt
minus-valid {⊤ᶜ} {⊤ᶜ} _ _ = tt
minus-valid {[ z₁ ]ᶜ} {[ z₂ ]ᶜ} refl refl = refl
minus-valid {[ z ]ᶜ} {⊤ᶜ} _ _ = tt
eval-valid : IsValidExprEvaluator
eval-valid (⇒ᵉ-+ ρ e₁ e₂ z₁ z₂ ρ,e₁⇒z₁ ρ,e₂⇒z₂) ⟦vs⟧ρ =
plus-valid (eval-valid ρ,e₁⇒z₁ ⟦vs⟧ρ) (eval-valid ρ,e₂⇒z₂ ⟦vs⟧ρ)
eval-valid (⇒ᵉ-- ρ e₁ e₂ z₁ z₂ ρ,e₁⇒z₁ ρ,e₂⇒z₂) ⟦vs⟧ρ =
minus-valid (eval-valid ρ,e₁⇒z₁ ⟦vs⟧ρ) (eval-valid ρ,e₂⇒z₂ ⟦vs⟧ρ)
eval-valid {vs} (⇒ᵉ-Var ρ x v x,v∈ρ) ⟦vs⟧ρ
with ∈k-decᵛ x (proj₁ (proj₁ vs))
... | yes x∈kvs = ⟦vs⟧ρ (proj₂ (locateᵛ {x} {vs} x∈kvs)) x,v∈ρ
... | no x∉kvs = tt
eval-valid (⇒ᵉ- ρ n) _ = refl
instance
ConstEvalValid : ValidExprEvaluator ConstEval latticeInterpretationᶜ
ConstEvalValid = record { valid = eval-valid }
analyze-correct = Analysis.Forward.WithProg.analyze-correct ConstLattice prog tt

374
Analysis/Forward.agda
View File

@@ -2,203 +2,35 @@ open import Language hiding (_[_])
open import Lattice
module Analysis.Forward
{L : Set} {h}
(L : Set) {h}
{_≈ˡ_ : L L Set} {_⊔ˡ_ : L L L} {_⊓ˡ_ : L L L}
(isFiniteHeightLatticeˡ : IsFiniteHeightLattice L h _≈ˡ_ _⊔ˡ_ _⊓ˡ_)
(≈ˡ-dec : IsDecidable _≈ˡ_) where
{{isFiniteHeightLatticeˡ : IsFiniteHeightLattice L h _≈ˡ_ _⊔ˡ_ _⊓ˡ_}}
{{≈ˡ-dec : IsDecidable _≈ˡ_}} where
open import Data.Empty using (⊥-elim)
open import Data.String using (String) renaming (_≟_ to _≟ˢ_)
open import Data.Nat using (suc)
open import Data.Product using (_×_; proj₁; proj₂; _,_)
open import Data.Sum using (inj₁; inj₂)
open import Data.List using (List; _∷_; []; foldr; foldl; cartesianProduct; cartesianProductWith)
open import Data.List.Membership.Propositional as MemProp using () renaming (_∈_ to _∈ˡ_)
open import Data.List.Relation.Unary.Any as Any using ()
open import Relation.Binary.PropositionalEquality using (_≡_; refl; cong; sym; trans; subst)
open import Relation.Nullary using (¬_; Dec; yes; no)
open import Data.Unit using ()
open import Data.String using (String)
open import Data.Product using (_,_)
open import Data.List using (_∷_; []; foldr; foldl)
open import Data.List.Relation.Unary.Any as Any using ()
open import Relation.Binary.PropositionalEquality using (_≡_; refl; cong; sym; subst)
open import Relation.Nullary using (yes; no)
open import Function using (_∘_; flip)
import Chain
open import Utils using (Pairwise; _⇒_; __)
import Lattice.FiniteValueMap
open IsFiniteHeightLattice isFiniteHeightLatticeˡ
using ()
renaming
( isLattice to isLatticeˡ
; fixedHeight to fixedHeightˡ
; _≼_ to _≼ˡ_
; ≈-sym to ≈ˡ-sym
)
using () renaming (isLattice to isLatticeˡ)
module WithProg (prog : Program) where
open import Analysis.Forward.Lattices L prog hiding (≈ᵛ-Decidable; ≈ᵐ-Decidable) -- to disambiguate instance resolution
open import Analysis.Forward.Evaluation L prog
open Program prog
-- The variable -> abstract value (e.g. sign) map is a finite value-map
-- with keys strings. Use a bundle to avoid explicitly specifying operators.
module VariableValuesFiniteMap = Lattice.FiniteValueMap.WithKeys _≟ˢ_ isLatticeˡ vars
open VariableValuesFiniteMap
using ()
renaming
( FiniteMap to VariableValues
; isLattice to isLatticeᵛ
; _≈_ to _≈ᵛ_
; _⊔_ to _⊔ᵛ_
; _≼_ to _≼ᵛ_
; ≈₂-dec⇒≈-dec to ≈ˡ-dec⇒≈ᵛ-dec
; _∈_ to _∈ᵛ_
; _∈k_ to _∈kᵛ_
; _updating_via_ to _updatingᵛ_via_
; locate to locateᵛ
; m₁≼m₂⇒m₁[k]≼m₂[k] to m₁≼m₂⇒m₁[k]ᵛ≼m₂[k]ᵛ
; ∈k-dec to ∈k-decᵛ
; all-equal-keys to all-equal-keysᵛ
)
public
open IsLattice isLatticeᵛ
using ()
renaming
( ⊔-Monotonicˡ to ⊔ᵛ-Monotonicˡ
; ⊔-Monotonicʳ to ⊔ᵛ-Monotonicʳ
; ⊔-idemp to ⊔ᵛ-idemp
)
open Lattice.FiniteValueMap.IterProdIsomorphism _≟ˢ_ isLatticeˡ
using ()
renaming
( Provenance-union to Provenance-unionᵐ
)
open Lattice.FiniteValueMap.IterProdIsomorphism.WithUniqueKeysAndFixedHeight _≟ˢ_ isLatticeˡ vars-Unique ≈ˡ-dec _ fixedHeightˡ
using ()
renaming
( isFiniteHeightLattice to isFiniteHeightLatticeᵛ
; ⊥-contains-bottoms to ⊥ᵛ-contains-bottoms
)
≈ᵛ-dec = ≈ˡ-dec⇒≈ᵛ-dec ≈ˡ-dec
joinSemilatticeᵛ = IsFiniteHeightLattice.joinSemilattice isFiniteHeightLatticeᵛ
fixedHeightᵛ = IsFiniteHeightLattice.fixedHeight isFiniteHeightLatticeᵛ
⊥ᵛ = Chain.Height.⊥ fixedHeightᵛ
-- Finally, the map we care about is (state -> (variables -> value)). Bring that in.
module StateVariablesFiniteMap = Lattice.FiniteValueMap.WithKeys _≟_ isLatticeᵛ states
open StateVariablesFiniteMap
using (_[_]; []-∈; m₁≼m₂⇒m₁[ks]≼m₂[ks]; m₁≈m₂⇒k∈m₁⇒k∈km₂⇒v₁≈v₂)
renaming
( FiniteMap to StateVariables
; isLattice to isLatticeᵐ
; _≈_ to _≈ᵐ_
; _∈_ to _∈ᵐ_
; _∈k_ to _∈kᵐ_
; locate to locateᵐ
; _≼_ to _≼ᵐ_
; ≈₂-dec⇒≈-dec to ≈ᵛ-dec⇒≈ᵐ-dec
; m₁≼m₂⇒m₁[k]≼m₂[k] to m₁≼m₂⇒m₁[k]ᵐ≼m₂[k]ᵐ
)
public
open Lattice.FiniteValueMap.IterProdIsomorphism.WithUniqueKeysAndFixedHeight _≟_ isLatticeᵛ states-Unique ≈ᵛ-dec _ fixedHeightᵛ
using ()
renaming
( isFiniteHeightLattice to isFiniteHeightLatticeᵐ
)
open IsFiniteHeightLattice isFiniteHeightLatticeᵐ
using ()
renaming
( ≈-sym to ≈ᵐ-sym
)
≈ᵐ-dec = ≈ᵛ-dec⇒≈ᵐ-dec ≈ᵛ-dec
fixedHeightᵐ = IsFiniteHeightLattice.fixedHeight isFiniteHeightLatticeᵐ
-- We now have our (state -> (variables -> value)) map.
-- Define a couple of helpers to retrieve values from it. Specifically,
-- since the State type is as specific as possible, it's always possible to
-- retrieve the variable values at each state.
states-in-Map : (s : State) (sv : StateVariables) s ∈kᵐ sv
states-in-Map s sv@(m , ksv≡states) rewrite ksv≡states = states-complete s
variablesAt : State StateVariables VariableValues
variablesAt s sv = proj₁ (locateᵐ {s} {sv} (states-in-Map s sv))
variablesAt-∈ : (s : State) (sv : StateVariables) (s , variablesAt s sv) ∈ᵐ sv
variablesAt-∈ s sv = proj₂ (locateᵐ {s} {sv} (states-in-Map s sv))
variablesAt-≈ : s sv₁ sv₂ sv₁ ≈ᵐ sv₂ variablesAt s sv₁ ≈ᵛ variablesAt s sv₂
variablesAt-≈ s sv₁ sv₂ sv₁≈sv₂ =
m₁≈m₂⇒k∈m₁⇒k∈km₂⇒v₁≈v₂ sv₁ sv₂ sv₁≈sv₂
(states-in-Map s sv₁) (states-in-Map s sv₂)
-- build up the 'join' function, which follows from Exercise 4.26's
--
-- L₁ → (A → L₂)
--
-- Construction, with L₁ = (A → L₂), and f = id
joinForKey : State StateVariables VariableValues
joinForKey k states = foldr _⊔ᵛ_ ⊥ᵛ (states [ incoming k ])
-- The per-key join is made up of map key accesses (which are monotonic)
-- and folds using the join operation (also monotonic)
joinForKey-Mono : (k : State) Monotonic _≼ᵐ_ _≼ᵛ_ (joinForKey k)
joinForKey-Mono k {fm₁} {fm₂} fm₁≼fm₂ =
foldr-Mono joinSemilatticeᵛ joinSemilatticeᵛ (fm₁ [ incoming k ]) (fm₂ [ incoming k ]) _⊔ᵛ_ ⊥ᵛ ⊥ᵛ
(m₁≼m₂⇒m₁[ks]≼m₂[ks] fm₁ fm₂ (incoming k) fm₁≼fm₂)
(⊔ᵛ-idemp ⊥ᵛ) ⊔ᵛ-Monotonicʳ ⊔ᵛ-Monotonicˡ
-- The name f' comes from the formulation of Exercise 4.26.
open StateVariablesFiniteMap.GeneralizedUpdate states isLatticeᵐ (λ x x) (λ a₁≼a₂ a₁≼a₂) joinForKey joinForKey-Mono states
renaming
( f' to joinAll
; f'-Monotonic to joinAll-Mono
; f'-k∈ks-≡ to joinAll-k∈ks-≡
)
variablesAt-joinAll : (s : State) (sv : StateVariables)
variablesAt s (joinAll sv) joinForKey s sv
variablesAt-joinAll s sv
with (vs , s,vs∈usv) locateᵐ {s} {joinAll sv} (states-in-Map s (joinAll sv)) =
joinAll-k∈ks-≡ {l = sv} (states-complete s) s,vs∈usv
-- With 'join' in hand, we need to perform abstract evaluation.
module WithEvaluator (eval : Expr VariableValues L)
(eval-Mono : (e : Expr) Monotonic _≼ᵛ_ _≼ˡ_ (eval e)) where
-- For a particular evaluation function, we need to perform an evaluation
-- for an assignment, and update the corresponding key. Use Exercise 4.26's
-- generalized update to set the single key's value.
private module _ (k : String) (e : Expr) where
open VariableValuesFiniteMap.GeneralizedUpdate vars isLatticeᵛ (λ x x) (λ a₁≼a₂ a₁≼a₂) (λ _ eval e) (λ _ {vs₁} {vs₂} vs₁≼vs₂ eval-Mono e {vs₁} {vs₂} vs₁≼vs₂) (k [])
renaming
( f' to updateVariablesFromExpression
; f'-Monotonic to updateVariablesFromExpression-Mono
; f'-k∈ks-≡ to updateVariablesFromExpression-k∈ks-≡
; f'-k∉ks-backward to updateVariablesFromExpression-k∉ks-backward
)
public
-- The per-state update function makes use of the single-key setter,
-- updateVariablesFromExpression, for the case where the statement
-- is an assignment.
--
-- This per-state function adjusts the variables in that state,
-- also monotonically; we derive the for-each-state update from
-- the Exercise 4.26 again.
updateVariablesFromStmt : BasicStmt VariableValues VariableValues
updateVariablesFromStmt (k e) vs = updateVariablesFromExpression k e vs
updateVariablesFromStmt noop vs = vs
updateVariablesFromStmt-Monoʳ : (bs : BasicStmt) Monotonic _≼ᵛ_ _≼ᵛ_ (updateVariablesFromStmt bs)
updateVariablesFromStmt-Monoʳ (k e) {vs₁} {vs₂} vs₁≼vs₂ = updateVariablesFromExpression-Mono k e {vs₁} {vs₂} vs₁≼vs₂
updateVariablesFromStmt-Monoʳ noop vs₁≼vs₂ = vs₁≼vs₂
private module WithStmtEvaluator {{evaluator : StmtEvaluator}} where
open StmtEvaluator evaluator
updateVariablesForState : State StateVariables VariableValues
updateVariablesForState s sv =
foldl (flip updateVariablesFromStmt) (variablesAt s sv) (code s)
foldl (flip (eval s)) (variablesAt s sv) (code s)
updateVariablesForState-Monoʳ : (s : State) Monotonic _≼ᵐ_ _≼ᵛ_ (updateVariablesForState s)
updateVariablesForState-Monoʳ s {sv₁} {sv₂} sv₁≼sv₂ =
@@ -209,15 +41,17 @@ module WithProg (prog : Program) where
vs₁≼vs₂ = m₁≼m₂⇒m₁[k]ᵐ≼m₂[k]ᵐ sv₁ sv₂ sv₁≼sv₂ s,vs₁∈sv₁ s,vs₂∈sv₂
in
foldl-Mono' (IsLattice.joinSemilattice isLatticeᵛ) bss
(flip updateVariablesFromStmt) updateVariablesFromStmt-Monoʳ
(flip (eval s)) (eval-Monoʳ s)
vs₁≼vs₂
open StateVariablesFiniteMap.GeneralizedUpdate states isLatticeᵐ (λ x x) (λ a₁≼a₂ a₁≼a₂) updateVariablesForState updateVariablesForState-Monoʳ states
open StateVariablesFiniteMap.GeneralizedUpdate {{isLatticeᵐ}} (λ x x) (λ a₁≼a₂ a₁≼a₂) updateVariablesForState updateVariablesForState-Monoʳ states
using ()
renaming
( f' to updateAll
; f'-Monotonic to updateAll-Mono
; f'-k∈ks-≡ to updateAll-k∈ks-≡
)
public
-- Finally, the whole analysis consists of getting the 'join'
-- of all incoming states, then applying the per-state evaluation
@@ -232,7 +66,7 @@ module WithProg (prog : Program) where
(joinAll-Mono {sv₁} {sv₂} sv₁≼sv₂)
-- The fixed point of the 'analyze' function is our final goal.
open import Fixedpoint ≈ᵐ-dec isFiniteHeightLatticeᵐ analyze (λ {m₁} {m₂} m₁≼m₂ analyze-Mono {m₁} {m₂} m₁≼m₂)
open import Fixedpoint analyze (λ {m₁} {m₂} m₁≼m₂ analyze-Mono {m₁} {m₂} m₁≼m₂)
using ()
renaming (aᶠ to result; aᶠ≈faᶠ to result≈analyze-result)
public
@@ -243,124 +77,68 @@ module WithProg (prog : Program) where
with (vs , s,vs∈usv) locateᵐ {s} {updateAll sv} (states-in-Map s (updateAll sv)) =
updateAll-k∈ks-≡ {l = sv} (states-complete s) s,vs∈usv
module WithInterpretation (latticeInterpretationˡ : LatticeInterpretation isLatticeˡ) where
open LatticeInterpretation latticeInterpretationˡ
using ()
renaming
( ⟦_⟧ to ⟦_⟧ˡ
; ⟦⟧-respects-≈ to ⟦⟧ˡ-respects-≈ˡ
; ⟦⟧-⊔- to ⟦⟧ˡ-⊔ˡ-
)
module WithValidInterpretation {{latticeInterpretationˡ : LatticeInterpretation isLatticeˡ}}
{{validEvaluator : ValidStmtEvaluator evaluator latticeInterpretationˡ}} (dummy : ) where
open ValidStmtEvaluator validEvaluator
⟦_⟧ᵛ : VariableValues Env Set
⟦_⟧ᵛ vs ρ = {k l} (k , l) ∈ᵛ vs {v} (k , v) Language.∈ ρ l ⟧ˡ v
eval-fold-valid : {s bss vs ρ₁ ρ₂} ρ₁ , bss ⇒ᵇˢ ρ₂ vs ⟧ᵛ ρ₁ foldl (flip (eval s)) vs bss ⟧ᵛ ρ₂
eval-fold-valid {_} [] ⟦vs⟧ρ = vs⟧ρ
eval-fold-valid {s} {bs bss'} {vs} {ρ₁} {ρ₂} (ρ₁,bs⇒ρ ρ,bss'⇒ρ₂) ⟦vs⟧ρ =
eval-fold-valid
{bss = bss'} {eval s bs vs} ρ,bss'⇒ρ₂
(valid ρ₁,bs⇒ρ ⟦vs⟧ρ)
⟦⊥ᵛ⟧ᵛ∅ : ⊥ᵛ ⟧ᵛ []
⟦⊥ᵛ⟧ᵛ∅ _ ()
updateVariablesForState-matches : {s sv ρ₁ ρ₂} ρ₁ , (code s) ⇒ᵇˢ ρ₂ variablesAt s sv ⟧ᵛ ρ₁ updateVariablesForState s sv ⟧ᵛ ρ₂
updateVariablesForState-matches = eval-fold-valid
⟦⟧ᵛ-respects-≈ᵛ : {vs₁ vs₂ : VariableValues} vs ≈ᵛ vs₂ vs₁ ⟧ᵛ vs₂ ⟧ᵛ
⟦⟧ᵛ-respects-≈ᵛ {m₁ , _} {m₂ , _}
(m₁⊆m₂ , m₂⊆m₁) ρ ⟦vs₁⟧ρ {k} {l} k,l∈m₂ {v} k,v∈ρ =
let
(l' , (l≈l' , k,l'∈m₁)) = m₂⊆m₁ _ _ k,l∈m₂
⟦l'⟧v = ⟦vs₁⟧ρ k,l'∈m₁ k,v∈ρ
in
⟦⟧ˡ-respects-≈ˡ (≈ˡ-sym l≈l') v ⟦l'⟧v
updateAll-matches : {s sv ρ₁ ρ₂} ρ , (code s) ⇒ᵇˢ ρ₂ variablesAt s sv ⟧ᵛ ρ₁ variablesAt s (updateAll sv) ⟧ᵛ ρ₂
updateAll-matches {s} {sv} ρ₁,bss⇒ρ ⟦vs⟧ρ
rewrite variablesAt-updateAll s sv =
updateVariablesForState-matches {s} {sv} ρ₁,bss⇒ρ ⟦vs⟧ρ
⟦⟧ᵛ-⊔ᵛ- : {vs₁ vs₂ : VariableValues} ( vs₁ ⟧ᵛ vs₂ ⟧ᵛ) vs₁ ⊔ᵛ vs₂ ⟧ᵛ
⟦⟧ᵛ-⊔ᵛ- {vs₁} {vs₂} ρ ⟦vs₁⟧ρ⟦vs₂⟧ρ {k} {l} k,l∈vs₁₂ {v} k,v∈ρ
with ((l₁ , l₂) , (refl , (k,l₁∈vs₁ , k,l₂∈vs₂)))
Provenance-unionᵐ vs₁ vs₂ k,l∈vs₁₂
with ⟦vs₁⟧ρ⟦vs₂⟧ρ
... | inj₁ ⟦vs₁⟧ρ = ⟦⟧ˡ-⊔ˡ- {l₁} {l₂} v (inj₁ (⟦vs₁⟧ρ k,l₁∈vs₁ k,v∈ρ))
... | inj₂ ⟦vs₂⟧ρ = ⟦⟧ˡ-⊔ˡ- {l₁} {l₂} v (inj₂ (⟦vs₂⟧ρ k,l₂∈vs₂ k,v∈ρ))
⟦⟧ᵛ-foldr : {vs : VariableValues} {vss : List VariableValues} {ρ : Env}
vs ⟧ᵛ ρ vs ∈ˡ vss foldr _⊔ᵛ_ ⊥ᵛ vss ⟧ᵛ ρ
⟦⟧ᵛ-foldr {vs} {vs vss'} {ρ = ρ} ⟦vs⟧ρ (Any.here refl) =
⟦⟧ᵛ-⊔ᵛ- {vs₁ = vs} {vs₂ = foldr _⊔ᵛ_ ⊥ᵛ vss'} ρ (inj₁ ⟦vs⟧ρ)
⟦⟧ᵛ-foldr {vs} {vs' vss'} {ρ = ρ} ⟦vs⟧ρ (Any.there vs∈vss') =
⟦⟧ᵛ-⊔ᵛ- {vs₁ = vs'} {vs₂ = foldr _⊔ᵛ_ ⊥ᵛ vss'} ρ
(inj₂ (⟦⟧ᵛ-foldr ⟦vs⟧ρ vs∈vss'))
InterpretationValid : Set
InterpretationValid = {vs ρ e v} ρ , e ⇒ᵉ v vs ⟧ᵛ ρ eval e vs ⟧ˡ v
module WithValidity (interpretationValidˡ : InterpretationValid) where
updateVariablesFromStmt-matches : {bs vs ρ₁ ρ₂} ρ₁ , bs ⇒ᵇ ρ₂ vs ⟧ᵛ ρ₁ updateVariablesFromStmt bs vs ⟧ᵛ ρ₂
updateVariablesFromStmt-matches {_} {vs} {ρ₁} {ρ₁} (⇒ᵇ-noop ρ₁) ⟦vs⟧ρ = ⟦vs⟧ρ
updateVariablesFromStmt-matches {_} {vs} {ρ₁} {_} (⇒ᵇ-← ρ₁ k e v ρ,e⇒v) ⟦vs⟧ρ {k'} {l} k',l∈vs' {v'} k',v'∈ρ₂
with k ≟ˢ k' | k',v'∈ρ₂
... | yes refl | here _ v _
rewrite updateVariablesFromExpression-k∈ks-≡ k e {l = vs} (Any.here refl) k',l∈vs' =
interpretationValidˡ ρ,e⇒v ⟦vs⟧ρ
... | yes k≡k' | there _ _ _ _ _ k'≢k _ = ⊥-elim (k'≢k (sym k≡k'))
... | no k≢k' | here _ _ _ = ⊥-elim (k≢k' refl)
... | no k≢k' | there _ _ _ _ _ _ k',v'∈ρ₁ =
let
k'∉[k] = (λ { (Any.here refl) k≢k' refl })
k',l∈vs = updateVariablesFromExpression-k∉ks-backward k e {l = vs} k'∉[k] k',l∈vs'
in
⟦vs⟧ρ k',l∈vs k',v'∈ρ₁
updateVariablesFromStmt-fold-matches : {bss vs ρ₁ ρ₂} ρ₁ , bss ⇒ᵇˢ ρ₂ vs ⟧ᵛ ρ₁ foldl (flip updateVariablesFromStmt) vs bss ⟧ᵛ ρ₂
updateVariablesFromStmt-fold-matches [] ⟦vs⟧ρ = ⟦vs⟧ρ
updateVariablesFromStmt-fold-matches {bs bss'} {vs} {ρ₁} {ρ₂} (ρ₁,bs⇒ρ ρ,bss'⇒ρ₂) ⟦vs⟧ρ =
updateVariablesFromStmt-fold-matches
{bss'} {updateVariablesFromStmt bs vs} ρ,bss'⇒ρ₂
(updateVariablesFromStmt-matches ρ₁,bs⇒ρ ⟦vs⟧ρ)
updateVariablesForState-matches : {s sv ρ₁ ρ₂} ρ₁ , (code s) ⇒ᵇˢ ρ₂ variablesAt s sv ⟧ᵛ ρ₁ updateVariablesForState s sv ⟧ᵛ ρ₂
updateVariablesForState-matches =
updateVariablesFromStmt-fold-matches
updateAll-matches : {s sv ρ₁ ρ₂} ρ₁ , (code s) ⇒ᵇˢ ρ₂ variablesAt s sv ⟧ᵛ ρ₁ variablesAt s (updateAll sv) ⟧ᵛ ρ₂
updateAll-matches {s} {sv} ρ₁,bss⇒ρ ⟦vs⟧ρ
rewrite variablesAt-updateAll s sv =
updateVariablesForState-matches {s} {sv} ρ₁,bss⇒ρ ⟦vs⟧ρ
stepTrace : {s₁ ρ₁ ρ₂} joinForKey s₁ result ⟧ᵛ ρ₁ ρ₁ , (code s₁) ⇒ᵇˢ ρ₂ variablesAt s₁ result ⟧ᵛ ρ₂
stepTrace {s₁} {ρ₁} {ρ₂} ⟦joinForKey-s₁⟧ρ ρ₁,bss⇒ρ =
let
-- I'd use rewrite, but Agda gets a memory overflow (?!).
⟦joinAll-result⟧ρ =
subst (λ vs vs ⟧ᵛ ρ₁)
(sym (variablesAt-joinAll s₁ result))
⟦joinForKey-s₁⟧ρ
⟦analyze-result⟧ρ =
updateAll-matches {sv = joinAll result}
ρ₁,bss⇒ρ ⟦joinAll-result⟧ρ
analyze-result≈result =
≈ᵐ-sym {result} {updateAll (joinAll result)}
result≈analyze-result
analyze-s₁≈s₁ =
variablesAt-≈ s₁ (updateAll (joinAll result))
result (analyze-result≈result)
in
⟦⟧ᵛ-respects-≈ᵛ {variablesAt s₁ (updateAll (joinAll result))} {variablesAt s₁ result} (analyze-s₁≈s₁) ρ₂ ⟦analyze-result⟧ρ
walkTrace : {s₁ s₂ ρ₁ ρ₂} joinForKey s₁ result ⟧ᵛ ρ₁ Trace {graph} s₁ s₂ ρ₁ ρ₂ variablesAt s₂ result ⟧ᵛ ρ₂
walkTrace {s₁} {s₁} {ρ₁} {ρ₂} ⟦joinForKey-s₁⟧ρ (Trace-single ρ₁,bss⇒ρ) =
stepTrace {s₁} {ρ₁} {ρ₂} ⟦joinForKey-s₁⟧ρ ρ₁,bss⇒ρ
walkTrace {s₁} {s₂} {ρ₁} {ρ₂} ⟦joinForKey-s₁⟧ρ (Trace-edge {ρ₂ = ρ} {idx₂ = s} ρ₁,bss⇒ρ s₁→s₂ tr) =
stepTrace : {s₁ ρ₁ ρ₂} joinForKey s₁ result ⟧ᵛ ρ₁ ρ₁ , (code s₁) ᵇˢ ρ₂ variablesAt s₁ result ⟧ᵛ ρ₂
stepTrace {s₁} {ρ₁} {ρ₂} ⟦joinForKey-s₁⟧ρ ρ₁,bss⇒ρ =
let
⟦result-s₁⟧ρ =
stepTrace {s₁} {ρ₁} {ρ} ⟦joinForKey-s₁⟧ρ ρ₁,bss⇒ρ
s₁∈incomingStates =
[]-∈ result (edge⇒incoming s₁→s₂)
(variablesAt-∈ s₁ result)
joinForKey-s⟧ρ =
⟦⟧ᵛ-foldr ⟦result-s₁⟧ρ s₁∈incomingStates
-- I'd use rewrite, but Agda gets a memory overflow (?!).
⟦joinAll-result⟧ρ =
subst (λ vs vs ⟧ᵛ ρ₁)
(sym (variablesAt-joinAll s₁ result))
⟦joinForKey-s₁⟧ρ
analyze-result⟧ρ =
updateAll-matches {sv = joinAll result}
ρ₁,bss⇒ρ ⟦joinAll-result⟧ρ
analyze-result≈result =
≈ᵐ-sym {result} {updateAll (joinAll result)}
result≈analyze-result
analyze-s₁≈s₁ =
variablesAt-≈ s₁ (updateAll (joinAll result))
result (analyze-result≈result)
in
walkTrace ⟦joinForKey-s⟧ρ tr
⟦⟧ᵛ-respects-≈ᵛ {variablesAt s₁ (updateAll (joinAll result))} {variablesAt s₁ result} (analyze-s₁≈s₁) ρ₂ ⟦analyze-result⟧ρ
joinForKey-initialState-⊥ᵛ : joinForKey initialState result ⊥ᵛ
joinForKey-initialState-⊥ᵛ = cong (λ ins foldr _⊔ᵛ_ ⊥ᵛ (result [ ins ])) initialState-pred-∅
walkTrace : {s₁ s₂ ρ₁ ρ₂} joinForKey s₁ result ⟧ᵛ ρ₁ Trace {graph} s₁ s₂ ρ₁ ρ₂ variablesAt s₂ result ⟧ᵛ ρ₂
walkTrace {s₁} {s₁} {ρ₁} {ρ₂} ⟦joinForKey-s₁⟧ρ (Trace-single ρ₁,bss⇒ρ) =
stepTrace {s₁} {ρ₁} {ρ₂} ⟦joinForKey-s₁⟧ρ ρ₁,bss⇒ρ
walkTrace {s₁} {s₂} {ρ₁} {ρ₂} ⟦joinForKey-s₁⟧ρ (Trace-edge {ρ₂ = ρ} {idx₂ = s} ρ₁,bss⇒ρ s₁→s₂ tr) =
let
⟦result-s₁⟧ρ =
stepTrace {s₁} {ρ₁} {ρ} ⟦joinForKey-s₁⟧ρ ρ₁,bss⇒ρ
s₁∈incomingStates =
[]-∈ result (edge⇒incoming s₁→s₂)
(variablesAt-∈ s₁ result)
⟦joinForKey-s⟧ρ =
⟦⟧ᵛ-foldr ⟦result-s₁⟧ρ s₁∈incomingStates
in
walkTrace ⟦joinForKey-s⟧ρ tr
joinAll-initialState⟧ᵛ∅ : joinForKey initialState result ⟧ᵛ []
⟦joinAll-initialState⟧ᵛ∅ = subst (λ vs vs []) (sym joinForKey-initialState-⊥ᵛ) ⟦⊥ᵛ⟧ᵛ
joinForKey-initialState-⊥ᵛ : joinForKey initialState result ⊥ᵛ
joinForKey-initialState-⊥ᵛ = cong (λ ins foldr _⊔ᵛ_ (result [ ins ])) initialState-pred-
analyze-correct : {ρ : Env} [] , rootStmt ⇒ˢ ρ variablesAt finalState result ⟧ᵛ ρ
analyze-correct {ρ} ∅,s⇒ρ = walkTrace {initialState} {finalState} {[]} {ρ} joinAll-initialState⟧ᵛ∅ (trace ∅,s⇒ρ)
⟦joinAll-initialState⟧ᵛ∅ : joinForKey initialState result ⟧ᵛ []
⟦joinAll-initialState⟧ᵛ∅ = subst (λ vs vs ⟧ᵛ []) (sym joinForKey-initialState-⊥ᵛ) ⟦⊥ᵛ⟧ᵛ∅
analyze-correct : {ρ : Env} [] , rootStmt ⇒ˢ ρ variablesAt finalState result ⟧ᵛ ρ
analyze-correct {ρ} ∅,s⇒ρ = walkTrace {initialState} {finalState} {[]} {ρ} ⟦joinAll-initialState⟧ᵛ∅ (trace ∅,s⇒ρ)
open WithStmtEvaluator using (result; analyze; result≈analyze-result) public
open WithStmtEvaluator.WithValidInterpretation using (analyze-correct) public

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open import Language hiding (_[_])
open import Lattice
module Analysis.Forward.Adapters
(L : Set) {h}
{_≈ˡ_ : L L Set} {_⊔ˡ_ : L L L} {_⊓ˡ_ : L L L}
{{isFiniteHeightLatticeˡ : IsFiniteHeightLattice L h _≈ˡ_ _⊔ˡ_ _⊓ˡ_}}
{{≈ˡ-dec : IsDecidable _≈ˡ_}}
(prog : Program) where
open import Analysis.Forward.Lattices L prog
open import Analysis.Forward.Evaluation L prog
open import Data.Empty using (⊥-elim)
open import Data.String using (String) renaming (_≟_ to _≟ˢ_)
open import Data.Product using (_,_)
open import Data.List using (_∷_; []; foldr; foldl)
open import Data.List.Relation.Unary.Any as Any using ()
open import Relation.Binary.PropositionalEquality using (_≡_; refl; cong; sym; subst)
open import Relation.Nullary using (yes; no)
open import Function using (_∘_; flip)
open IsFiniteHeightLattice isFiniteHeightLatticeˡ
using ()
renaming
( isLattice to isLatticeˡ
; _≼_ to _≼ˡ_
)
open Program prog
-- Now, allow StmtEvaluators to be auto-constructed from ExprEvaluators.
module ExprToStmtAdapter {{ exprEvaluator : ExprEvaluator }} where
open ExprEvaluator exprEvaluator
using ()
renaming
( eval to evalᵉ
; eval-Monoʳ to evalᵉ-Monoʳ
)
-- For a particular evaluation function, we need to perform an evaluation
-- for an assignment, and update the corresponding key. Use Exercise 4.26's
-- generalized update to set the single key's value.
private module _ (k : String) (e : Expr) where
open VariableValuesFiniteMap.GeneralizedUpdate {{isLatticeᵛ}} (λ x x) (λ a₁≼a₂ a₁≼a₂) (λ _ evalᵉ e) (λ _ {vs₁} {vs₂} vs₁≼vs₂ evalᵉ-Monoʳ e {vs₁} {vs₂} vs₁≼vs₂) (k [])
using ()
renaming
( f' to updateVariablesFromExpression
; f'-Monotonic to updateVariablesFromExpression-Mono
; f'-k∈ks-≡ to updateVariablesFromExpression-k∈ks-≡
; f'-k∉ks-backward to updateVariablesFromExpression-k∉ks-backward
)
public
-- The per-state update function makes use of the single-key setter,
-- updateVariablesFromExpression, for the case where the statement
-- is an assignment.
--
-- This per-state function adjusts the variables in that state,
-- also monotonically; we derive the for-each-state update from
-- the Exercise 4.26 again.
evalᵇ : State BasicStmt VariableValues VariableValues
evalᵇ _ (k e) vs = updateVariablesFromExpression k e vs
evalᵇ _ noop vs = vs
evalᵇ-Monoʳ : (s : State) (bs : BasicStmt) Monotonic _≼ᵛ_ _≼ᵛ_ (evalᵇ s bs)
evalᵇ-Monoʳ _ (k e) {vs₁} {vs₂} vs₁≼vs₂ = updateVariablesFromExpression-Mono k e {vs₁} {vs₂} vs₁≼vs₂
evalᵇ-Monoʳ _ noop vs₁≼vs₂ = vs₁≼vs₂
instance
stmtEvaluator : StmtEvaluator
stmtEvaluator = record { eval = evalᵇ ; eval-Monoʳ = evalᵇ-Monoʳ }
-- Moreover, correct StmtEvaluators can be constructed from correct
-- ExprEvaluators.
module _ {{latticeInterpretationˡ : LatticeInterpretation isLatticeˡ}}
{{isValid : ValidExprEvaluator exprEvaluator latticeInterpretationˡ}} where
open ValidExprEvaluator isValid using () renaming (valid to validᵉ)
evalᵇ-valid : {s vs ρ₁ ρ₂ bs} ρ₁ , bs ⇒ᵇ ρ₂ vs ⟧ᵛ ρ₁ evalᵇ s bs vs ⟧ᵛ ρ₂
evalᵇ-valid {_} {vs} {ρ₁} {ρ₁} {_} (⇒ᵇ-noop ρ₁) ⟦vs⟧ρ = ⟦vs⟧ρ
evalᵇ-valid {_} {vs} {ρ₁} {_} {_} (⇒ᵇ-← ρ₁ k e v ρ,e⇒v) ⟦vs⟧ρ {k'} {l} k',l∈vs' {v'} k',v'∈ρ₂
with k ≟ˢ k' | k',v'∈ρ₂
... | yes refl | here _ v _
rewrite updateVariablesFromExpression-k∈ks-≡ k e {l = vs} (Any.here refl) k',l∈vs' =
validᵉ ρ,e⇒v ⟦vs⟧ρ
... | yes k≡k' | there _ _ _ _ _ k'≢k _ = ⊥-elim (k'≢k (sym k≡k'))
... | no k≢k' | here _ _ _ = ⊥-elim (k≢k' refl)
... | no k≢k' | there _ _ _ _ _ _ k',v'∈ρ₁ =
let
k'∉[k] = (λ { (Any.here refl) k≢k' refl })
k',l∈vs = updateVariablesFromExpression-k∉ks-backward k e {l = vs} k'∉[k] k',l∈vs'
in
⟦vs⟧ρ k',l∈vs k',v'∈ρ₁
instance
validStmtEvaluator : ValidStmtEvaluator stmtEvaluator latticeInterpretationˡ
validStmtEvaluator = record
{ valid = λ {a} {b} {c} {d} evalᵇ-valid {a} {b} {c} {d}
}

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open import Language hiding (_[_])
open import Lattice
module Analysis.Forward.Evaluation
(L : Set) {h}
{_≈ˡ_ : L L Set} {_⊔ˡ_ : L L L} {_⊓ˡ_ : L L L}
{{isFiniteHeightLatticeˡ : IsFiniteHeightLattice L h _≈ˡ_ _⊔ˡ_ _⊓ˡ_}}
{{≈ˡ-dec : IsDecidable _≈ˡ_}}
(prog : Program) where
open import Analysis.Forward.Lattices L prog
open import Data.Product using (_,_)
open IsFiniteHeightLattice isFiniteHeightLatticeˡ
using ()
renaming
( isLattice to isLatticeˡ
; _≼_ to _≼ˡ_
)
open Program prog
-- The "full" version of the analysis ought to define a function
-- that analyzes each basic statement. For some analyses, the state ID
-- is used as part of the lattice, so include it here.
record StmtEvaluator : Set where
field
eval : State BasicStmt VariableValues VariableValues
eval-Monoʳ : (s : State) (bs : BasicStmt) Monotonic _≼ᵛ_ _≼ᵛ_ (eval s bs)
-- For some "simpler" analyes, all we need to do is analyze the expressions.
-- For that purpose, provide a simpler evaluator type.
record ExprEvaluator : Set where
field
eval : Expr VariableValues L
eval-Monoʳ : (e : Expr) Monotonic _≼ᵛ_ _≼ˡ_ (eval e)
-- Evaluators have a notion of being "valid", in which the (symbolic)
-- manipulations on lattice elements they perform match up with
-- the semantics. Define what it means to be valid for statement and
-- expression-based evaluators. Define "IsValidExprEvaluator"
-- and "IsValidStmtEvaluator" standalone so that users can use them
-- in their type expressions.
module _ {{evaluator : ExprEvaluator}} {{interpretation : LatticeInterpretation isLatticeˡ}} where
open ExprEvaluator evaluator
open LatticeInterpretation interpretation
IsValidExprEvaluator : Set
IsValidExprEvaluator = {vs ρ e v} ρ , e ⇒ᵉ v vs ⟧ᵛ ρ eval e vs ⟧ˡ v
record ValidExprEvaluator (evaluator : ExprEvaluator)
(interpretation : LatticeInterpretation isLatticeˡ) : Set where
field
valid : IsValidExprEvaluator {{evaluator}} {{interpretation}}
module _ {{evaluator : StmtEvaluator}} {{interpretation : LatticeInterpretation isLatticeˡ}} where
open StmtEvaluator evaluator
open LatticeInterpretation interpretation
IsValidStmtEvaluator : Set
IsValidStmtEvaluator = {s vs ρ₁ ρ₂ bs} ρ₁ , bs ⇒ᵇ ρ₂ vs ⟧ᵛ ρ₁ eval s bs vs ⟧ᵛ ρ₂
record ValidStmtEvaluator (evaluator : StmtEvaluator)
(interpretation : LatticeInterpretation isLatticeˡ) : Set where
field
valid : IsValidStmtEvaluator {{evaluator}} {{interpretation}}

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open import Language hiding (_[_])
open import Lattice
module Analysis.Forward.Lattices
(L : Set) {h}
{_≈ˡ_ : L L Set} {_⊔ˡ_ : L L L} {_⊓ˡ_ : L L L}
{{isFiniteHeightLatticeˡ : IsFiniteHeightLattice L h _≈ˡ_ _⊔ˡ_ _⊓ˡ_}}
{{≈ˡ-Decidable : IsDecidable _≈ˡ_}}
(prog : Program) where
open import Data.String using (String) renaming (_≟_ to _≟ˢ_)
open import Data.Product using (proj₁; proj₂; _,_)
open import Data.Sum using (inj₁; inj₂)
open import Data.List using (List; _∷_; []; foldr)
open import Data.List.Membership.Propositional using () renaming (_∈_ to _∈ˡ_)
open import Data.List.Relation.Unary.Any as Any using ()
open import Relation.Binary.PropositionalEquality using (_≡_; refl)
open import Utils using (Pairwise; _⇒_; __; it)
open IsFiniteHeightLattice isFiniteHeightLatticeˡ
using ()
renaming
( isLattice to isLatticeˡ
; fixedHeight to fixedHeightˡ
; ≈-sym to ≈ˡ-sym
)
open Program prog
import Lattice.FiniteMap
import Chain
instance
≡-Decidable-String = record { R-dec = _≟ˢ_ }
≡-Decidable-State = record { R-dec = _≟_ }
-- The variable -> abstract value (e.g. sign) map is a finite value-map
-- with keys strings. Use a bundle to avoid explicitly specifying operators.
-- It's helpful to export these via 'public' since consumers tend to
-- use various variable lattice operations.
module VariableValuesFiniteMap = Lattice.FiniteMap String L vars
open VariableValuesFiniteMap
using ()
renaming
( FiniteMap to VariableValues
; isLattice to isLatticeᵛ
; _≈_ to _≈ᵛ_
; _⊔_ to _⊔ᵛ_
; _≼_ to _≼ᵛ_
; ≈-Decidable to ≈ᵛ-Decidable
; _∈_ to _∈ᵛ_
; _∈k_ to _∈kᵛ_
; _updating_via_ to _updatingᵛ_via_
; locate to locateᵛ
; m₁≼m₂⇒m₁[k]≼m₂[k] to m₁≼m₂⇒m₁[k]ᵛ≼m₂[k]ᵛ
; ∈k-dec to ∈k-decᵛ
; all-equal-keys to all-equal-keysᵛ
; Provenance-union to Provenance-unionᵛ
; ⊔-Monotonicˡ to ⊔ᵛ-Monotonicˡ
; ⊔-Monotonicʳ to ⊔ᵛ-Monotonicʳ
; ⊔-idemp to ⊔ᵛ-idemp
)
public
open VariableValuesFiniteMap.FixedHeight vars-Unique
using ()
renaming
( isFiniteHeightLattice to isFiniteHeightLatticeᵛ
; fixedHeight to fixedHeightᵛ
; ⊥-contains-bottoms to ⊥ᵛ-contains-bottoms
)
public
⊥ᵛ = Chain.Height.⊥ fixedHeightᵛ
-- Finally, the map we care about is (state -> (variables -> value)). Bring that in.
module StateVariablesFiniteMap = Lattice.FiniteMap State VariableValues states
open StateVariablesFiniteMap
using (_[_]; []-∈; m₁≼m₂⇒m₁[ks]≼m₂[ks]; m₁≈m₂⇒k∈m₁⇒k∈km₂⇒v₁≈v₂)
renaming
( FiniteMap to StateVariables
; isLattice to isLatticeᵐ
; _≈_ to _≈ᵐ_
; _∈_ to _∈ᵐ_
; _∈k_ to _∈kᵐ_
; locate to locateᵐ
; _≼_ to _≼ᵐ_
; ≈-Decidable to ≈ᵐ-Decidable
; m₁≼m₂⇒m₁[k]≼m₂[k] to m₁≼m₂⇒m₁[k]ᵐ≼m₂[k]ᵐ
; ≈-sym to ≈ᵐ-sym
)
public
open StateVariablesFiniteMap.FixedHeight states-Unique
using ()
renaming
( isFiniteHeightLattice to isFiniteHeightLatticeᵐ
)
public
-- We now have our (state -> (variables -> value)) map.
-- Define a couple of helpers to retrieve values from it. Specifically,
-- since the State type is as specific as possible, it's always possible to
-- retrieve the variable values at each state.
states-in-Map : (s : State) (sv : StateVariables) s ∈kᵐ sv
states-in-Map s sv@(m , ksv≡states) rewrite ksv≡states = states-complete s
variablesAt : State StateVariables VariableValues
variablesAt s sv = proj₁ (locateᵐ {s} {sv} (states-in-Map s sv))
variablesAt-∈ : (s : State) (sv : StateVariables) (s , variablesAt s sv) ∈ᵐ sv
variablesAt-∈ s sv = proj₂ (locateᵐ {s} {sv} (states-in-Map s sv))
variablesAt-≈ : s sv₁ sv₂ sv₁ ≈ᵐ sv₂ variablesAt s sv₁ ≈ᵛ variablesAt s sv₂
variablesAt-≈ s sv₁ sv₂ sv₁≈sv₂ =
m₁≈m₂⇒k∈m₁⇒k∈km₂⇒v₁≈v₂ sv₁ sv₂ sv₁≈sv₂
(states-in-Map s sv₁) (states-in-Map s sv₂)
-- build up the 'join' function, which follows from Exercise 4.26's
--
-- L₁ → (A → L₂)
--
-- Construction, with L₁ = (A → L₂), and f = id
joinForKey : State StateVariables VariableValues
joinForKey k states = foldr _⊔ᵛ_ ⊥ᵛ (states [ incoming k ])
-- The per-key join is made up of map key accesses (which are monotonic)
-- and folds using the join operation (also monotonic)
joinForKey-Mono : (k : State) Monotonic _≼ᵐ_ _≼ᵛ_ (joinForKey k)
joinForKey-Mono k {fm₁} {fm₂} fm₁≼fm₂ =
foldr-Mono it it (fm₁ [ incoming k ]) (fm₂ [ incoming k ]) _⊔ᵛ_ ⊥ᵛ ⊥ᵛ
(m₁≼m₂⇒m₁[ks]≼m₂[ks] fm₁ fm₂ (incoming k) fm₁≼fm₂)
(⊔ᵛ-idemp ⊥ᵛ) ⊔ᵛ-Monotonicʳ ⊔ᵛ-Monotonicˡ
-- The name f' comes from the formulation of Exercise 4.26.
open StateVariablesFiniteMap.GeneralizedUpdate {{isLatticeᵐ}} (λ x x) (λ a₁≼a₂ a₁≼a₂) joinForKey joinForKey-Mono states
using ()
renaming
( f' to joinAll
; f'-Monotonic to joinAll-Mono
; f'-k∈ks-≡ to joinAll-k∈ks-≡
)
public
variablesAt-joinAll : (s : State) (sv : StateVariables)
variablesAt s (joinAll sv) joinForKey s sv
variablesAt-joinAll s sv
with (vs , s,vs∈usv) locateᵐ {s} {joinAll sv} (states-in-Map s (joinAll sv)) =
joinAll-k∈ks-≡ {l = sv} (states-complete s) s,vs∈usv
-- Elements of the lattice type L describe individual variables. What
-- exactly each lattice element says about the variable is defined
-- by a LatticeInterpretation element. We've now constructed the
-- (Variable → L) lattice, which describes states, and we need to lift
-- the "meaning" of the element lattice to a descriptions of states.
module _ {{latticeInterpretationˡ : LatticeInterpretation isLatticeˡ}} where
open LatticeInterpretation latticeInterpretationˡ
using ()
renaming
( ⟦_⟧ to ⟦_⟧ˡ
; ⟦⟧-respects-≈ to ⟦⟧ˡ-respects-≈ˡ
; ⟦⟧-⊔- to ⟦⟧ˡ-⊔ˡ-
)
public
⟦_⟧ᵛ : VariableValues Env Set
⟦_⟧ᵛ vs ρ = {k l} (k , l) ∈ᵛ vs {v} (k , v) Language.∈ ρ l ⟧ˡ v
⟦⊥ᵛ⟧ᵛ∅ : ⊥ᵛ ⟧ᵛ []
⟦⊥ᵛ⟧ᵛ∅ _ ()
⟦⟧ᵛ-respects-≈ᵛ : {vs₁ vs₂ : VariableValues} vs₁ ≈ᵛ vs₂ vs₁ ⟧ᵛ vs₂ ⟧ᵛ
⟦⟧ᵛ-respects-≈ᵛ {m₁ , _} {m₂ , _}
(m₁⊆m₂ , m₂⊆m₁) ρ ⟦vs₁⟧ρ {k} {l} k,l∈m₂ {v} k,v∈ρ =
let
(l' , (l≈l' , k,l'∈m₁)) = m₂⊆m₁ _ _ k,l∈m₂
⟦l'⟧v = ⟦vs₁⟧ρ k,l'∈m₁ k,v∈ρ
in
⟦⟧ˡ-respects-≈ˡ (≈ˡ-sym l≈l') v ⟦l'⟧v
⟦⟧ᵛ-⊔ᵛ- : {vs₁ vs₂ : VariableValues} ( vs₁ ⟧ᵛ vs₂ ⟧ᵛ) vs₁ ⊔ᵛ vs₂ ⟧ᵛ
⟦⟧ᵛ-⊔ᵛ- {vs₁} {vs₂} ρ ⟦vs₁⟧ρ⟦vs₂⟧ρ {k} {l} k,l∈vs₁₂ {v} k,v∈ρ
with ((l₁ , l₂) , (refl , (k,l₁∈vs₁ , k,l₂∈vs₂)))
Provenance-unionᵛ vs₁ vs₂ k,l∈vs₁₂
with ⟦vs₁⟧ρ⟦vs₂⟧ρ
... | inj₁ ⟦vs₁⟧ρ = ⟦⟧ˡ-⊔ˡ- {l₁} {l₂} v (inj₁ (⟦vs₁⟧ρ k,l₁∈vs₁ k,v∈ρ))
... | inj₂ ⟦vs₂⟧ρ = ⟦⟧ˡ-⊔ˡ- {l₁} {l₂} v (inj₂ (⟦vs₂⟧ρ k,l₂∈vs₂ k,v∈ρ))
⟦⟧ᵛ-foldr : {vs : VariableValues} {vss : List VariableValues} {ρ : Env}
vs ⟧ᵛ ρ vs ∈ˡ vss foldr _⊔ᵛ_ ⊥ᵛ vss ⟧ᵛ ρ
⟦⟧ᵛ-foldr {vs} {vs vss'} {ρ = ρ} ⟦vs⟧ρ (Any.here refl) =
⟦⟧ᵛ-⊔ᵛ- {vs₁ = vs} {vs₂ = foldr _⊔ᵛ_ ⊥ᵛ vss'} ρ (inj₁ ⟦vs⟧ρ)
⟦⟧ᵛ-foldr {vs} {vs' vss'} {ρ = ρ} ⟦vs⟧ρ (Any.there vs∈vss') =
⟦⟧ᵛ-⊔ᵛ- {vs₁ = vs'} {vs₂ = foldr _⊔ᵛ_ ⊥ᵛ vss'} ρ
(inj₂ (⟦⟧ᵛ-foldr ⟦vs⟧ρ vs∈vss'))

125
Analysis/Sign.agda
View File

@@ -7,13 +7,16 @@ open import Data.Sum using (inj₁; inj₂)
open import Data.Empty using (⊥; ⊥-elim)
open import Data.Unit using (; tt)
open import Data.List.Membership.Propositional as MemProp using () renaming (_∈_ to _∈ˡ_)
open import Relation.Binary.Definitions using (Decidable)
open import Relation.Binary.PropositionalEquality using (_≡_; refl; sym; trans; subst)
open import Relation.Nullary using (¬_; yes; no)
open import Language
open import Lattice
open import Equivalence
open import Showable using (Showable; show)
open import Utils using (_⇒_; _∧_; __)
open import Analysis.Utils using (eval-combine₂)
import Analysis.Forward
data Sign : Set where
@@ -32,7 +35,7 @@ instance
}
-- g for siGn; s is used for strings and i is not very descriptive.
_≟ᵍ_ : IsDecidable (_≡_ {_} {Sign})
_≟ᵍ_ : Decidable (_≡_ {_} {Sign})
_≟ᵍ_ + + = yes refl
_≟ᵍ_ + - = no (λ ())
_≟ᵍ_ + 0ˢ = no (λ ())
@@ -43,12 +46,22 @@ _≟ᵍ_ 0ˢ + = no (λ ())
_≟ᵍ_ 0ˢ - = no (λ ())
_≟ᵍ_ 0ˢ 0ˢ = yes refl
instance
≡-equiv : IsEquivalence Sign _≡_
≡-equiv = record
{ ≈-refl = refl
; ≈-sym = sym
; ≈-trans = trans
}
≡-Decidable-Sign : IsDecidable {_} {Sign} _≡_
≡-Decidable-Sign = record { R-dec = _≟ᵍ_ }
-- embelish 'sign' with a top and bottom element.
open import Lattice.AboveBelow Sign _≡_ (record { ≈-refl = refl; ≈-sym = sym; ≈-trans = trans }) _≟ᵍ_ as AB
open import Lattice.AboveBelow Sign _ as AB
using ()
renaming
( AboveBelow to SignLattice
; ≈-dec to ≈ᵍ-dec
; to ⊥ᵍ
; to ⊤ᵍ
; [_] to [_]ᵍ
@@ -62,15 +75,11 @@ open import Lattice.AboveBelow Sign _≡_ (record { ≈-refl = refl; ≈-sym = s
open AB.Plain 0ˢ using ()
renaming
( isLattice to isLatticeᵍ
; fixedHeight to fixedHeight
; isFiniteHeightLattice to isFiniteHeightLattice
; _≼_ to _≼ᵍ_
; _⊔_ to _⊔ᵍ_
; _⊓_ to _⊓ᵍ_
)
open IsLattice isLatticeᵍ using ()
renaming
( ≼-trans to ≼ᵍ-trans
; ≼-trans to ≼ᵍ-trans
)
plus : SignLattice SignLattice SignLattice
@@ -93,6 +102,9 @@ plus [ 0ˢ ]ᵍ [ 0ˢ ]ᵍ = [ 0ˢ ]ᵍ
postulate plus-Monoˡ : (s₂ : SignLattice) Monotonic _≼ᵍ_ _≼ᵍ_ (λ s₁ plus s₁ s₂)
postulate plus-Monoʳ : (s₁ : SignLattice) Monotonic _≼ᵍ_ _≼ᵍ_ (plus s₁)
plus-Mono₂ : Monotonic₂ _≼ᵍ_ _≼ᵍ_ _≼ᵍ_ plus
plus-Mono₂ = (plus-Monoˡ , plus-Monoʳ)
minus : SignLattice SignLattice SignLattice
minus ⊥ᵍ _ = ⊥ᵍ
minus _ ⊥ᵍ = ⊥ᵍ
@@ -111,6 +123,9 @@ minus [ 0ˢ ]ᵍ [ 0ˢ ]ᵍ = [ 0ˢ ]ᵍ
postulate minus-Monoˡ : (s₂ : SignLattice) Monotonic _≼ᵍ_ _≼ᵍ_ (λ s₁ minus s₁ s₂)
postulate minus-Monoʳ : (s₁ : SignLattice) Monotonic _≼ᵍ_ _≼ᵍ_ (minus s₁)
minus-Mono₂ : Monotonic₂ _≼ᵍ_ _≼ᵍ_ _≼ᵍ_ minus
minus-Mono₂ = (minus-Monoˡ , minus-Monoʳ)
⟦_⟧ᵍ : SignLattice Value Set
⟦_⟧ᵍ ⊥ᵍ _ =
⟦_⟧ᵍ ⊤ᵍ _ =
@@ -159,19 +174,21 @@ s₁≢s₂⇒¬s₁∧s₂ { - } { - } +≢+ _ = ⊥-elim (+≢+ refl)
⟦⟧ᵍ-⊓ᵍ-∧ {[ g₁ ]ᵍ} {⊥ᵍ} x (_ , bot) = bot
⟦⟧ᵍ-⊓ᵍ-∧ {[ g₁ ]ᵍ} {⊤ᵍ} x (px₁ , _) = px₁
latticeInterpretationᵍ : LatticeInterpretation isLatticeᵍ
latticeInterpretationᵍ = record
{ ⟦_⟧ = ⟦_⟧ᵍ
; ⟦⟧-respects-≈ = ⟦⟧ᵍ-respects-≈
; ⟦⟧-⊔- = ⟦⟧ᵍ-⊔ᵍ-
; ⟦⟧-⊓-∧ = ⟦⟧ᵍ-ᵍ-
}
instance
latticeInterpretationᵍ : LatticeInterpretation isLatticeᵍ
latticeInterpretationᵍ = record
{ ⟦_⟧ = ⟦_⟧
; ⟦⟧-respects-≈ = ⟦⟧ᵍ-respects-≈ᵍ
; ⟦⟧-⊔- = ⟦⟧ᵍ-ᵍ-
; ⟦⟧-⊓-∧ = ⟦⟧ᵍ-⊓ᵍ-∧
}
module WithProg (prog : Program) where
open Program prog
module ForwardWithProg = Analysis.Forward.WithProg (record { isLattice = isLatticeᵍ; fixedHeight = fixedHeightᵍ }) ≈ᵍ-dec prog
open ForwardWithProg
open import Analysis.Forward.Lattices SignLattice prog
open import Analysis.Forward.Evaluation SignLattice prog
open import Analysis.Forward.Adapters SignLattice prog
eval : (e : Expr) VariableValues SignLattice
eval (e₁ + e₂) vs = plus (eval e₁ vs) (eval e₂ vs)
@@ -183,32 +200,16 @@ module WithProg (prog : Program) where
eval (# 0) _ = [ 0ˢ ]ᵍ
eval (# (suc n')) _ = [ + ]ᵍ
eval-Mono : (e : Expr) Monotonic _≼ᵛ_ _≼ᵍ_ (eval e)
eval-Mono (e₁ + e₂) {vs₁} {vs₂} vs₁≼vs₂ =
let
-- TODO: can this be done with less boilerplate?
g₁vs₁ = eval e vs₁
g₂vs₁ = eval e₂ vs₁
g₁vs₂ = eval e₁ vs₂
g₂vs₂ = eval e vs
in
≼ᵍ-trans
{plus g₁vs₁ g₂vs₁} {plus g₁vs₂ g₂vs₁} {plus g₁vs₂ g₂vs₂}
(plus-Monoˡ g₂vs₁ {g₁vs₁} {g₁vs₂} (eval-Mono e₁ {vs₁} {vs₂} vs₁≼vs₂))
(plus-Monoʳ g₁vs₂ {g₂vs₁} {g₂vs₂} (eval-Mono e₂ {vs₁} {vs₂} vs₁≼vs₂))
eval-Mono (e₁ - e₂) {vs₁} {vs₂} vs₁≼vs₂ =
let
-- TODO: here too -- can this be done with less boilerplate?
g₁vs₁ = eval e₁ vs₁
g₂vs₁ = eval e₂ vs₁
g₁vs₂ = eval e₁ vs₂
g₂vs₂ = eval e₂ vs₂
in
≼ᵍ-trans
{minus g₁vs₁ g₂vs₁} {minus g₁vs₂ g₂vs₁} {minus g₁vs₂ g₂vs₂}
(minus-Monoˡ g₂vs₁ {g₁vs₁} {g₁vs₂} (eval-Mono e₁ {vs₁} {vs₂} vs₁≼vs₂))
(minus-Monoʳ g₁vs₂ {g₂vs₁} {g₂vs₂} (eval-Mono e₂ {vs₁} {vs₂} vs₁≼vs₂))
eval-Mono (` k) {vs₁@((kvs₁ , _) , _)} {vs₂@((kvs₂ , _), _)} vs₁≼vs₂
eval-Monoʳ : (e : Expr) Monotonic _≼ᵛ_ _≼ᵍ_ (eval e)
eval-Monoʳ (e₁ + e₂) {vs₁} {vs₂} vs₁≼vs₂ =
eval-combine₂ (λ {x} {y} {z} ≼ᵍ-trans {x} {y} {z})
plus plus-Mono₂ {o₁ = eval e₁ vs₁}
(eval-Monoʳ e₁ vs₁≼vs₂) (eval-Monoʳ e vs₁≼vs₂)
eval-Monoʳ (e₁ - e₂) {vs₁} {vs₂} vs₁≼vs₂ =
eval-combine₂ (λ {x} {y} {z} ≼ᵍ-trans {x} {y} {z})
minus minus-Mono₂ {o₁ = eval e vs}
(eval-Monoʳ e₁ vs₁≼vs₂) (eval-Monoʳ e₂ vs₁≼vs₂)
eval-Monoʳ (` k) {vs₁@((kvs₁ , _) , _)} {vs₂@((kvs₂ , _), _)} vs₁≼vs₂
with ∈k-decᵛ k kvs₁ | ∈k-decᵛ k kvs₂
... | yes k∈kvs₁ | yes k∈kvs₂ =
let
@@ -219,17 +220,15 @@ module WithProg (prog : Program) where
... | yes k∈kvs₁ | no k∉kvs₂ = ⊥-elim (k∉kvs₂ (subst (λ l k ∈ˡ l) (all-equal-keysᵛ vs₁ vs₂) k∈kvs₁))
... | no k∉kvs₁ | yes k∈kvs₂ = ⊥-elim (k∉kvs₁ (subst (λ l k ∈ˡ l) (all-equal-keysᵛ vs₂ vs₁) k∈kvs₂))
... | no k∉kvs₁ | no k∉kvs₂ = IsLattice.≈-refl isLatticeᵍ
eval-Mono (# 0) _ = ≈ᵍ-refl
eval-Mono (# (suc n')) _ = ≈ᵍ-refl
eval-Monoʳ (# 0) _ = ≈ᵍ-refl
eval-Monoʳ (# (suc n')) _ = ≈ᵍ-refl
module ForwardWithEval = ForwardWithProg.WithEvaluator eval eval-Mono
open ForwardWithEval using (result)
instance
SignEval : ExprEvaluator
SignEval = record { eval = eval; eval-Monoʳ = eval-Monoʳ }
-- For debugging purposes, print out the result.
output = show result
module ForwardWithInterp = ForwardWithEval.WithInterpretation latticeInterpretationᵍ
open ForwardWithInterp using (⟦_⟧ᵛ; InterpretationValid)
output = show (Analysis.Forward.WithProg.result SignLattice prog)
-- This should have fewer cases -- the same number as the actual 'plus' above.
-- But agda only simplifies on first argument, apparently, so we are stuck
@@ -281,16 +280,20 @@ module WithProg (prog : Program) where
minus-valid {[ 0ˢ ]ᵍ} {[ 0ˢ ]ᵍ} refl refl = refl
minus-valid {[ 0ˢ ]ᵍ} {⊤ᵍ} _ _ = tt
eval-Valid : InterpretationValid
eval-Valid (⇒ᵉ-+ ρ e₁ e₂ z₁ z₂ ρ,e₁⇒z₁ ρ,e₂⇒z₂) ⟦vs⟧ρ =
plus-valid (eval-Valid ρ,e₁⇒z₁ ⟦vs⟧ρ) (eval-Valid ρ,e₂⇒z₂ ⟦vs⟧ρ)
eval-Valid (⇒ᵉ-- ρ e₁ e₂ z₁ z₂ ρ,e₁⇒z₁ ρ,e₂⇒z₂) ⟦vs⟧ρ =
minus-valid (eval-Valid ρ,e₁⇒z₁ ⟦vs⟧ρ) (eval-Valid ρ,e₂⇒z₂ ⟦vs⟧ρ)
eval-Valid {vs} (⇒ᵉ-Var ρ x v x,v∈ρ) ⟦vs⟧ρ
eval-valid : IsValidExprEvaluator
eval-valid (⇒ᵉ-+ ρ e₁ e₂ z₁ z₂ ρ,e₁⇒z₁ ρ,e₂⇒z₂) ⟦vs⟧ρ =
plus-valid (eval-valid ρ,e₁⇒z₁ ⟦vs⟧ρ) (eval-valid ρ,e₂⇒z₂ ⟦vs⟧ρ)
eval-valid (⇒ᵉ-- ρ e₁ e₂ z₁ z₂ ρ,e₁⇒z₁ ρ,e₂⇒z₂) ⟦vs⟧ρ =
minus-valid (eval-valid ρ,e₁⇒z₁ ⟦vs⟧ρ) (eval-valid ρ,e₂⇒z₂ ⟦vs⟧ρ)
eval-valid {vs} (⇒ᵉ-Var ρ x v x,v∈ρ) ⟦vs⟧ρ
with ∈k-decᵛ x (proj₁ (proj₁ vs))
... | yes x∈kvs = ⟦vs⟧ρ (proj₂ (locateᵛ {x} {vs} x∈kvs)) x,v∈ρ
... | no x∉kvs = tt
eval-Valid (⇒ᵉ- ρ 0) _ = refl
eval-Valid (⇒ᵉ- ρ (suc n')) _ = (n' , refl)
eval-valid (⇒ᵉ- ρ 0) _ = refl
eval-valid (⇒ᵉ- ρ (suc n')) _ = (n' , refl)
open ForwardWithInterp.WithValidity eval-Valid using (analyze-correct) public
instance
SignEvalValid : ValidExprEvaluator SignEval latticeInterpretationᵍ
SignEvalValid = record { valid = eval-valid }
analyze-correct = Analysis.Forward.WithProg.analyze-correct SignLattice prog tt

15
Analysis/Utils.agda Normal file
View File

@@ -0,0 +1,15 @@
module Analysis.Utils where
open import Data.Product using (_,_)
open import Lattice
module _ {o} {O : Set o} {_≼ᴼ_ : O O Set o}
(≼ᴼ-trans : {o₁ o₂ o₃} o₁ ≼ᴼ o₂ o₂ ≼ᴼ o₃ o₁ ≼ᴼ o₃)
(combine : O O O) (combine-Mono₂ : Monotonic₂ _≼ᴼ_ _≼ᴼ_ _≼ᴼ_ combine) where
eval-combine₂ : {o₁ o₂ o₃ o₄ : O} o₁ ≼ᴼ o₃ o₂ ≼ᴼ o₄
combine o₁ o₂ ≼ᴼ combine o₃ o₄
eval-combine₂ {o₁} {o₂} {o₃} {o₄} o₁≼o₃ o₂≼o₄ =
let (combine-Monoˡ , combine-Monoʳ) = combine-Mono₂
in ≼ᴼ-trans (combine-Monoˡ o₂ o₁≼o₃)
(combine-Monoʳ o₃ o₂≼o₄)

24
Fixedpoint.agda
View File

@@ -5,8 +5,8 @@ module Fixedpoint {a} {A : Set a}
{h : }
{_≈_ : A A Set a}
{_⊔_ : A A A} {_⊓_ : A A A}
(≈-dec : IsDecidable _≈_)
(flA : IsFiniteHeightLattice A h _≈_ _⊔_ _⊓_)
{{ ≈-Decidable : IsDecidable _≈_ }}
{{flA : IsFiniteHeightLattice A h _≈_ _⊔_ _⊓_}}
(f : A A)
(Monotonicᶠ : Monotonic (IsFiniteHeightLattice._≼_ flA)
(IsFiniteHeightLattice._≼_ flA) f) where
@@ -17,6 +17,7 @@ open import Data.Empty using (⊥-elim)
open import Relation.Binary.PropositionalEquality using (_≡_; sym)
open import Relation.Nullary using (Dec; ¬_; yes; no)
open IsDecidable ≈-Decidable using () renaming (R-dec to ≈-dec)
open IsFiniteHeightLattice flA
import Chain
@@ -27,24 +28,9 @@ private
using ()
renaming
( to ⊥ᴬ
; longestChain to longestChainᴬ
; bounded to boundedᴬ
)
⊥ᴬ≼ : (a : A) ⊥ᴬ a
⊥ᴬ≼ a with ≈-dec a ⊥ᴬ
... | yes a≈⊥ᴬ = ≼-cong a≈⊥ᴬ ≈-refl (≼-refl a)
... | no a̷≈⊥ᴬ with ≈-dec ⊥ᴬ (a ⊥ᴬ)
... | yes ⊥ᴬ≈a⊓⊥ᴬ = ≈-trans (⊔-comm ⊥ᴬ a) (≈-trans (≈-⊔-cong (≈-refl {a}) ⊥ᴬ≈a⊓⊥ᴬ) (absorb-⊔-⊓ a ⊥ᴬ))
... | no ⊥ᴬ̷≈a⊓⊥ᴬ = ⊥-elim (ChainA.Bounded-suc-n boundedᴬ (ChainA.step x≺⊥ᴬ ≈-refl longestChainᴬ))
where
⊥ᴬ⊓a̷≈⊥ᴬ : ¬ (⊥ᴬ a) ⊥ᴬ
⊥ᴬ⊓a̷≈⊥ᴬ = λ ⊥ᴬ⊓a≈⊥ᴬ ⊥ᴬ̷≈a⊓⊥ᴬ (≈-trans (≈-sym ⊥ᴬ⊓a≈⊥ᴬ) (⊓-comm _ _))
x≺⊥ᴬ : (⊥ᴬ a) ⊥ᴬ
x≺⊥ᴬ = (≈-trans (⊔-comm _ _) (≈-trans (≈-refl {⊥ᴬ (⊥ᴬ a)}) (absorb-⊔-⊓ ⊥ᴬ a)) , ⊥ᴬ⊓a̷≈⊥ᴬ)
-- using 'g', for gas, here helps make sure the function terminates.
-- since A forms a fixed-height lattice, we must find a solution after
-- 'h' steps at most. Gas is set up such that as soon as it runs
@@ -64,7 +50,7 @@ private
c' rewrite +-comm 1 hᶜ = ChainA.concat c (ChainA.step a₂≺fa₂ ≈-refl (ChainA.done (≈-refl {f a₂})))
fix : Σ A (λ a a f a)
fix = doStep (suc h) 0 ⊥ᴬ ⊥ᴬ (ChainA.done ≈-refl) (+-comm (suc h) 0) ( (f ⊥ᴬ))
fix = doStep (suc h) 0 ⊥ᴬ ⊥ᴬ (ChainA.done ≈-refl) (+-comm (suc h) 0) (⊥≼ (f ⊥ᴬ))
aᶠ : A
aᶠ = proj₁ fix
@@ -84,4 +70,4 @@ private
... | no _ = stepPreservesLess g' _ _ _ b b≈fb (≼-cong ≈-refl (≈-sym b≈fb) (Monotonicᶠ a₂≼b)) _ _ _
aᶠ≼ : (a : A) a f a aᶠ a
aᶠ≼ a a≈fa = stepPreservesLess (suc h) 0 ⊥ᴬ ⊥ᴬ a a≈fa ( a) (ChainA.done ≈-refl) (+-comm (suc h) 0) ( (f ⊥ᴬ))
aᶠ≼ a a≈fa = stepPreservesLess (suc h) 0 ⊥ᴬ ⊥ᴬ a a≈fa (⊥≼ a) (ChainA.done ≈-refl) (+-comm (suc h) 0) (⊥≼ (f ⊥ᴬ))

47
Isomorphism.agda
View File

@@ -63,27 +63,30 @@ module TransportFiniteHeight
portChain₂ (done₂ a₂≈a₁) = done₁ (g-preserves-≈₂ a₂≈a₁)
portChain₂ (step₂ {b₁} {b₂} (b₁≼b₂ , b₁̷≈b₂) b₂≈b₂' c) = step₁ (≈₁-trans (≈₁-sym (g-⊔-distr b₁ b₂)) (g-preserves-≈₂ b₁≼b₂) , g-preserves-̷≈ b₁̷≈b₂) (g-preserves-≈₂ b₂≈b₂') (portChain₂ c)
isFiniteHeightLattice : IsFiniteHeightLattice B height _≈₂_ _⊔₂_ _⊓₂_
isFiniteHeightLattice =
let
open Chain.Height (IsFiniteHeightLattice.fixedHeight fhlA)
using ()
renaming ( to ⊥₁; to ⊤₁; bounded to bounded₁; longestChain to c)
in record
{ isLattice = lB
; fixedHeight = record
{ = f ⊥₁
; = f ⊤₁
; longestChain = portChain₁ c
; bounded = λ c' bounded₁ (portChain₂ c')
}
open Chain.Height (IsFiniteHeightLattice.fixedHeight fhlA)
using ()
renaming ( to ⊥₁; to ⊤₁; bounded to bounded₁; longestChain to c)
instance
fixedHeight : IsLattice.FixedHeight lB height
fixedHeight = record
{ = f ⊥₁
; = f ⊤₁
; longestChain = portChain₁ c
; bounded = λ c' bounded₁ (portChain₂ c')
}
finiteHeightLattice : FiniteHeightLattice B
finiteHeightLattice = record
{ height = height
; _≈_ = _≈₂_
; _⊔_ = _⊔₂_
; _⊓_ = _⊓₂_
; isFiniteHeightLattice = isFiniteHeightLattice
}
isFiniteHeightLattice : IsFiniteHeightLattice B height _≈₂_ _⊔₂_ _⊓₂_
isFiniteHeightLattice = record
{ isLattice = lB
; fixedHeight = fixedHeight
}
finiteHeightLattice : FiniteHeightLattice B
finiteHeightLattice = record
{ height = height
; _≈_ = _≈₂_
; _⊔_ = _⊔₂_
; _⊓_ = _⊓₂_
; isFiniteHeightLattice = isFiniteHeightLattice
}

7
Language.agda
View File

@@ -16,12 +16,13 @@ open import Data.Nat using (; suc)
open import Data.Product using (_,_; Σ; proj₁; proj₂)
open import Data.Product.Properties as ProdProp using ()
open import Data.String using (String) renaming (_≟_ to _≟ˢ_)
open import Relation.Binary.Definitions using (Decidable)
open import Relation.Binary.PropositionalEquality using (_≡_; refl)
open import Relation.Nullary using (¬_)
open import Lattice
open import Utils using (Unique; push; Unique-map; x∈xs⇒fx∈fxs)
open import Lattice.MapSet _≟ˢ_ using ()
open import Lattice.MapSet String {{record { R-dec = _≟ˢ_ }}} _ using ()
renaming
( MapSet to StringSet
; to-List to to-Listˢ
@@ -73,10 +74,10 @@ record Program : Set where
-- vars-complete : ∀ {k : String} (s : State) → k ∈ᵇ (code s) → k ListMem.∈ vars
-- vars-complete {k} s = ∈⇒∈-Stmts-vars {length} {k} {stmts} {s}
_≟_ : IsDecidable (_≡_ {_} {State})
_≟_ : Decidable (_≡_ {_} {State})
_≟_ = FinProp._≟_
_≟ᵉ_ : IsDecidable (_≡_ {_} {Graph.Edge graph})
_≟ᵉ_ : Decidable (_≡_ {_} {Graph.Edge graph})
_≟ᵉ_ = ProdProp.≡-dec _≟_ _≟_
open import Data.List.Membership.DecPropositional _≟ᵉ_ using (_∈?_)

2
Language/Base.agda
View File

@@ -39,7 +39,7 @@ data _∈ᵇ_ : String → BasicStmt → Set where
in←₁ : {k : String} {e : Expr} k ∈ᵇ (k e)
in←₂ : {k k' : String} {e : Expr} k ∈ᵉ e k ∈ᵇ (k' e)
open import Lattice.MapSet (String._≟_)
open import Lattice.MapSet String {{record { R-dec = String._≟_ }}} _
renaming
( MapSet to StringSet
; insert to insertˢ

35
Language/Graphs.agda
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@@ -12,7 +12,6 @@ open import Data.List.Relation.Unary.Any as RelAny using ()
open import Data.Nat as Nat using (; suc)
open import Data.Nat.Properties using (+-assoc; +-comm)
open import Data.Product using (_×_; Σ; _,_; proj₁; proj₂)
open import Data.Product.Properties as ProdProp using ()
open import Data.Vec using (Vec; []; _∷_; lookup; cast; _++_)
open import Data.Vec.Properties using (cast-is-id; ++-assoc; lookup-++ˡ; cast-sym; ++-identityʳ; lookup-++ʳ)
open import Relation.Binary.PropositionalEquality as Eq using (_≡_; sym; refl; subst; trans)
@@ -125,39 +124,21 @@ buildCfg (s₁ then s₂) = buildCfg s₁ ↦ buildCfg s₂
buildCfg (if _ then s₁ else s₂) = buildCfg s₁ buildCfg s₂
buildCfg (while _ repeat s) = loop (buildCfg s)
private
z≢sf : {n : } (f : Fin n) ¬ (zero suc f)
z≢sf f ()
z≢mapsfs : {n : } (fs : List (Fin n)) All (λ sf ¬ zero sf) (List.map suc fs)
z≢mapsfs [] = []
z≢mapsfs (f fs') = z≢sf f z≢mapsfs fs'
finValues : (n : ) Σ (List (Fin n)) Unique
finValues 0 = ([] , Utils.empty)
finValues (suc n') =
let
(inds' , unids') = finValues n'
in
( zero List.map suc inds'
, push (z≢mapsfs inds') (Unique-map suc suc-injective unids')
)
finValues-complete : (n : ) (f : Fin n) f ListMem.∈ (proj₁ (finValues n))
finValues-complete (suc n') zero = RelAny.here refl
finValues-complete (suc n') (suc f') = RelAny.there (x∈xs⇒fx∈fxs suc (finValues-complete n' f'))
module _ (g : Graph) where
open import Data.List.Membership.DecPropositional (ProdProp.≡-dec (FinProp._≟_ {Graph.size g}) (FinProp._≟_ {Graph.size g})) using (_∈?_)
open import Data.Product.Properties as ProdProp using ()
private _≟_ = ProdProp.≡-dec (FinProp._≟_ {Graph.size g})
(FinProp._≟_ {Graph.size g})
open import Data.List.Membership.DecPropositional (_≟_) using (_∈?_)
indices : List (Graph.Index g)
indices = proj₁ (finValues (Graph.size g))
indices = proj₁ (fins (Graph.size g))
indices-complete : (idx : (Graph.Index g)) idx ListMem.∈ indices
indices-complete = finValues-complete (Graph.size g)
indices-complete = fins-complete (Graph.size g)
indices-Unique : Unique indices
indices-Unique = proj₂ (finValues (Graph.size g))
indices-Unique = proj₂ (fins (Graph.size g))
predecessors : (Graph.Index g) List (Graph.Index g)
predecessors idx = List.filter (λ idx' (idx' , idx) ∈? (Graph.edges g)) indices

56
Lattice.agda
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@@ -4,15 +4,17 @@ open import Equivalence
import Chain
open import Relation.Binary.Core using (_Preserves_⟶_ )
open import Relation.Nullary using (Dec; ¬_)
open import Relation.Nullary using (Dec; ¬_; yes; no)
open import Data.Empty using (⊥-elim)
open import Data.Nat as Nat using ()
open import Data.Product using (_×_; Σ; _,_)
open import Data.Sum using (_⊎_; inj₁; inj₂)
open import Agda.Primitive using (lsuc; Level) renaming (_⊔_ to _⊔_)
open import Function.Definitions using (Injective)
IsDecidable : {a} {A : Set a} (R : A A Set a) Set a
IsDecidable {a} {A} R = (a₁ a₂ : A) Dec (R a₁ a₂)
record IsDecidable {a} {A : Set a} (R : A A Set a) : Set a where
field
R-dec : (a₁ a₂ : A) Dec (R a₁ a₂)
module _ {a b} {A : Set a} {B : Set b}
(_≼₁_ : A A Set a) (_≼₂_ : B B Set b) where
@@ -20,6 +22,18 @@ module _ {a b} {A : Set a} {B : Set b}
Monotonic : (A B) Set (a ⊔ℓ b)
Monotonic f = {a₁ a₂ : A} a₁ ≼₁ a₂ f a₁ ≼₂ f a₂
Monotonicˡ : {c} {C : Set c} (A C B) Set (a ⊔ℓ b ⊔ℓ c)
Monotonicˡ f = c Monotonic (λ a f a c)
Monotonicʳ : {c} {C : Set c} (C A B) Set (a ⊔ℓ b ⊔ℓ c)
Monotonicʳ f = a Monotonic (f a)
module _ {a b c} {A : Set a} {B : Set b} {C : Set c}
(_≼₁_ : A A Set a) (_≼₂_ : B B Set b) (_≼₃_ : C C Set c) where
Monotonic₂ : (A B C) Set (a ⊔ℓ b ⊔ℓ c)
Monotonic₂ f = Monotonicˡ _≼₁_ _≼₃_ f × Monotonicʳ _≼₂_ _≼₃_ f
record IsSemilattice {a} (A : Set a)
(_≈_ : A A Set a)
(_⊔_ : A A A) : Set a where
@@ -186,8 +200,8 @@ record IsLattice {a} (A : Set a)
(_⊓_ : A A A) : Set a where
field
joinSemilattice : IsSemilattice A _≈_ _⊔_
meetSemilattice : IsSemilattice A _≈_ _⊓_
{{joinSemilattice}} : IsSemilattice A _≈_ _⊔_
{{meetSemilattice}} : IsSemilattice A _≈_ _⊓_
absorb-⊔-⊓ : (x y : A) (x (x y)) x
absorb-⊓-⊔ : (x y : A) (x (x y)) x
@@ -216,12 +230,34 @@ record IsFiniteHeightLattice {a} (A : Set a)
(_⊓_ : A A A) : Set (lsuc a) where
field
isLattice : IsLattice A _≈_ _⊔_ _⊓_
{{isLattice}} : IsLattice A _≈_ _⊔_ _⊓_
open IsLattice isLattice public
field
fixedHeight : FixedHeight h
{{fixedHeight}} : FixedHeight h
-- If the equality is decidable, we can prove that the top and bottom
-- elements of the chain are least and greatest elements of the lattice
module _ {{≈-Decidable : IsDecidable _≈_}} where
open IsDecidable ≈-Decidable using () renaming (R-dec to ≈-dec)
module MyChain = Chain _≈_ ≈-equiv _≺_ ≺-cong
open MyChain.Height fixedHeight using (⊥; ) public
open MyChain.Height fixedHeight using (bounded; longestChain)
⊥≼ : (a : A) a
⊥≼ a with ≈-dec a
... | yes a≈⊥ = ≼-cong a≈⊥ ≈-refl (≼-refl a)
... | no a̷≈⊥ with ≈-dec (a )
... | yes ⊥≈a⊓⊥ = ≈-trans (⊔-comm a) (≈-trans (≈-⊔-cong (≈-refl {a}) ⊥≈a⊓⊥) (absorb-⊔-⊓ a ))
... | no ⊥ᴬ̷≈a⊓⊥ = ⊥-elim (MyChain.Bounded-suc-n bounded (MyChain.step x≺⊥ ≈-refl longestChain))
where
⊥⊓a̷≈⊥ : ¬ ( a)
⊥⊓a̷≈⊥ = λ ⊥⊓a≈⊥ ⊥ᴬ̷≈a⊓⊥ (≈-trans (≈-sym ⊥⊓a≈⊥) (⊓-comm _ _))
x≺⊥ : ( a)
x≺⊥ = (≈-trans (⊔-comm _ _) (≈-trans (≈-refl { ( a)}) (absorb-⊔-⊓ a)) , ⊥⊓a̷≈⊥)
module ChainMapping {a b} {A : Set a} {B : Set b}
{_≈₁_ : A A Set a} {_≈₂_ : B B Set b}
@@ -251,7 +287,7 @@ record Semilattice {a} (A : Set a) : Set (lsuc a) where
_≈_ : A A Set a
_⊔_ : A A A
isSemilattice : IsSemilattice A _≈_ _⊔_
{{isSemilattice}} : IsSemilattice A _≈_ _⊔_
open IsSemilattice isSemilattice public
@@ -262,7 +298,7 @@ record Lattice {a} (A : Set a) : Set (lsuc a) where
_⊔_ : A A A
_⊓_ : A A A
isLattice : IsLattice A _≈_ _⊔_ _⊓_
{{isLattice}} : IsLattice A _≈_ _⊔_ _⊓_
open IsLattice isLattice public
@@ -273,6 +309,6 @@ record FiniteHeightLattice {a} (A : Set a) : Set (lsuc a) where
_⊔_ : A A A
_⊓_ : A A A
isFiniteHeightLattice : IsFiniteHeightLattice A height _≈_ _⊔_ _⊓_
{{isFiniteHeightLattice}} : IsFiniteHeightLattice A height _≈_ _⊔_ _⊓_
open IsFiniteHeightLattice isFiniteHeightLattice public

122
Lattice/AboveBelow.agda
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@@ -1,17 +1,19 @@
open import Lattice
open import Equivalence
open import Relation.Nullary using (Dec; ¬_; yes; no)
open import Data.Unit using () renaming ( to ⊤ᵘ)
module Lattice.AboveBelow {a} (A : Set a)
(_≈₁_ : A A Set a)
(≈₁-equiv : IsEquivalence A _≈₁_)
(≈₁-dec : IsDecidable _≈₁_) where
{_≈₁_ : A A Set a}
{{≈₁-equiv : IsEquivalence A _≈₁_}}
{{≈₁-Decidable : IsDecidable _≈₁_}} (dummy : ⊤ᵘ) where
open import Data.Empty using (⊥-elim)
open import Data.Product using (_,_)
open import Data.Nat using (_≤_; ; z≤n; s≤s; suc)
open import Function using (_∘_)
open import Showable using (Showable; show)
open import Relation.Binary.Definitions using (Decidable)
open import Relation.Binary.PropositionalEquality as Eq
using (_≡_; sym; subst; refl)
@@ -20,6 +22,8 @@ import Chain
open IsEquivalence ≈₁-equiv using ()
renaming (≈-refl to ≈₁-refl; ≈-sym to ≈₁-sym; ≈-trans to ≈₁-trans)
open IsDecidable ≈₁-Decidable using () renaming (R-dec to ≈₁-dec)
data AboveBelow : Set a where
: AboveBelow
: AboveBelow
@@ -62,7 +66,7 @@ data _≈_ : AboveBelow → AboveBelow → Set a where
; ≈-trans = ≈-trans
}
≈-dec : IsDecidable _≈_
≈-dec : Decidable _≈_
≈-dec = yes ≈-⊥-⊥
≈-dec = yes ≈--
≈-dec [ x ] [ y ]
@@ -76,6 +80,10 @@ data _≈_ : AboveBelow → AboveBelow → Set a where
≈-dec [ x ] = no λ ()
≈-dec [ x ] = no λ ()
instance
≈-Decidable : IsDecidable _≈_
≈-Decidable = record { R-dec = ≈-dec }
-- Any object can be wrapped in an 'above below' to make it a lattice,
-- since and ⊥ are the largest and least elements, and the rest are left
-- unordered. That's what this module does.
@@ -169,14 +177,15 @@ module Plain (x : A) where
⊔-idemp = ≈-⊥-⊥
⊔-idemp [ x ] rewrite x≈y⇒[x]⊔[y]≡[x] (≈₁-refl {x}) = ≈-refl
isJoinSemilattice : IsSemilattice AboveBelow _≈_ _⊔_
isJoinSemilattice = record
{ ≈-equiv = ≈-equiv
; ≈-⊔-cong = ≈-⊔-cong
; ⊔-assoc = ⊔-assoc
; ⊔-comm = ⊔-comm
; ⊔-idemp = ⊔-idemp
}
instance
isJoinSemilattice : IsSemilattice AboveBelow _≈_ _⊔_
isJoinSemilattice = record
{ ≈-equiv = ≈-equiv
; ≈-⊔-cong = ≈-⊔-cong
; ⊔-assoc = ⊔-assoc
; ⊔-comm = ⊔-comm
; ⊔-idemp = ⊔-idemp
}
_⊓_ : AboveBelow AboveBelow AboveBelow
x =
@@ -262,14 +271,15 @@ module Plain (x : A) where
⊓-idemp = ≈--
⊓-idemp [ x ] rewrite x≈y⇒[x]⊓[y]≡[x] (≈₁-refl {x}) = ≈-refl
isMeetSemilattice : IsSemilattice AboveBelow _≈_ _⊓_
isMeetSemilattice = record
{ ≈-equiv = ≈-equiv
; ≈-⊔-cong = ≈-⊓-cong
; ⊔-assoc = ⊓-assoc
; ⊔-comm = ⊓-comm
; ⊔-idemp = ⊓-idemp
}
instance
isMeetSemilattice : IsSemilattice AboveBelow _≈_ _⊓_
isMeetSemilattice = record
{ ≈-equiv = ≈-equiv
; ≈-⊔-cong = ≈-⊓-cong
; ⊔-assoc = ⊓-assoc
; ⊔-comm = ⊓-comm
; ⊔-idemp = ⊓-idemp
}
absorb-⊔-⊓ : (ab₁ ab₂ : AboveBelow) (ab₁ (ab₁ ab₂)) ab₁
absorb-⊔-⊓ ab₂ rewrite ⊥⊓x≡⊥ ab₂ = ≈-⊥-⊥
@@ -294,23 +304,24 @@ module Plain (x : A) where
... | no x̷≈y rewrite x̷≈y⇒[x]⊔[y]≡⊤ x̷≈y rewrite x⊓≡x [ x ] = ≈-refl
isLattice : IsLattice AboveBelow _≈_ _⊔_ _⊓_
isLattice = record
{ joinSemilattice = isJoinSemilattice
; meetSemilattice = isMeetSemilattice
; absorb-⊔-⊓ = absorb-⊔-⊓
; absorb-⊓- = absorb-⊓-
}
instance
isLattice : IsLattice AboveBelow _≈_ _⊔_ _⊓_
isLattice = record
{ joinSemilattice = isJoinSemilattice
; meetSemilattice = isMeetSemilattice
; absorb-⊔-⊓ = absorb-⊔-⊓
; absorb-⊓-⊔ = absorb-⊓-⊔
}
lattice : Lattice AboveBelow
lattice = record
{ _≈_ = _≈_
; _⊔_ = _⊔_
; _⊓_ = _⊓_
; isLattice = isLattice
}
lattice : Lattice AboveBelow
lattice = record
{ _≈_ = _≈_
; _⊔_ = _⊔_
; _⊓_ = _⊓_
; isLattice = isLattice
}
open IsLattice isLattice using (_≼_; _≺_; ⊔-Monotonicˡ; ⊔-Monotonicʳ) public
open IsLattice isLattice using (_≼_; _≺_; ≼-trans; ≼-refl; ⊔-Monotonicˡ; ⊔-Monotonicʳ) public
⊥≺[x] : (x : A) [ x ]
⊥≺[x] x = (≈-refl , λ ())
@@ -354,25 +365,26 @@ module Plain (x : A) where
isLongest {} (step {_} {[ x ]} _ (≈-lift _) (step [x]≺y y≈z c@(step _ _ _)))
rewrite [x]≺y⇒y≡ _ _ [x]≺y with ≈-- y≈z = ⊥-elim (¬-Chain- c)
fixedHeight : IsLattice.FixedHeight isLattice 2
fixedHeight = record
{ =
; =
; longestChain = longestChain
; bounded = isLongest
}
instance
fixedHeight : IsLattice.FixedHeight isLattice 2
fixedHeight = record
{ =
; =
; longestChain = longestChain
; bounded = isLongest
}
isFiniteHeightLattice : IsFiniteHeightLattice AboveBelow 2 _≈_ _⊔_ _⊓_
isFiniteHeightLattice = record
{ isLattice = isLattice
; fixedHeight = fixedHeight
}
isFiniteHeightLattice : IsFiniteHeightLattice AboveBelow 2 _≈_ _⊔_ _⊓_
isFiniteHeightLattice = record
{ isLattice = isLattice
; fixedHeight = fixedHeight
}
finiteHeightLattice : FiniteHeightLattice AboveBelow
finiteHeightLattice = record
{ height = 2
; _≈_ = _≈_
; _⊔_ = _⊔_
; _⊓_ = _⊓_
; isFiniteHeightLattice = isFiniteHeightLattice
}
finiteHeightLattice : FiniteHeightLattice AboveBelow
finiteHeightLattice = record
{ height = 2
; _≈_ = _≈_
; _⊔_ = _⊔_
; _⊓_ = _⊓_
; isFiniteHeightLattice = isFiniteHeightLattice
}

381
Lattice/Builder.agda Normal file
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@@ -0,0 +1,381 @@
module Lattice.Builder where
open import Lattice
open import Equivalence
open import Utils using (Unique; push; empty; Unique-append; Unique-++⁻ˡ; Unique-++⁻ʳ; Unique-narrow; All¬-¬Any; ¬Any-map; fins; fins-complete; findUniversal; Decidable-¬)
open import Data.Nat as Nat using ()
open import Data.Fin as Fin using (Fin; suc; zero; _≟_)
open import Data.Maybe as Maybe using (Maybe; just; nothing; _>>=_; maybe)
open import Data.Maybe.Properties using (just-injective)
open import Data.Unit using (; tt)
open import Data.List.NonEmpty using (List⁺; tail; toList) renaming (_∷_ to _∷⁺_)
open import Data.List.Membership.Propositional as MemProp using (lose) renaming (_∈_ to _∈ˡ_; mapWith∈ to mapWith∈ˡ)
open import Data.List.Membership.Propositional.Properties using () renaming (∈-++⁺ʳ to ∈ˡ-++⁺ʳ; ∈-++⁺ˡ to ∈ˡ-++⁺ˡ; ∈-cartesianProductWith⁺ to ∈ˡ-cartesianProductWith⁺)
open import Data.List.Relation.Unary.Any using (Any; here; there; any?; satisfied)
open import Data.List.Relation.Unary.Any.Properties using (¬Any[])
open import Data.List.Relation.Unary.All using (All; []; _∷_; map; lookup; zipWith; tabulate; all?)
open import Data.List.Relation.Unary.All.Properties using () renaming (++⁺ to ++ˡ⁺; ++⁻ʳ to ++ˡ⁻ʳ)
open import Data.List using (List; _∷_; []; cartesianProduct; cartesianProductWith; foldr) renaming (_++_ to _++ˡ_)
open import Data.List.Properties using () renaming (++-conicalʳ to ++ˡ-conicalʳ; ++-identityʳ to ++ˡ-identityʳ; ++-assoc to ++ˡ-assoc)
open import Data.Sum using (_⊎_; inj₁; inj₂)
open import Data.Product using (Σ; _,_; _×_; proj₁; proj₂; uncurry)
open import Data.Empty using (⊥; ⊥-elim)
open import Relation.Nullary using (¬_; Dec; yes; no; ¬?)
open import Relation.Binary.PropositionalEquality as Eq using (_≡_; refl; sym; trans; cong; subst)
open import Relation.Binary.PropositionalEquality.Properties using (decSetoid)
open import Relation.Binary using () renaming (Decidable to Decidable²)
open import Relation.Unary using (Decidable)
open import Agda.Primitive using (lsuc; Level) renaming (_⊔_ to _⊔_)
record Graph : Set where
constructor mkGraph
field
size :
Node : Set
Node = Fin size
nodes = fins size
nodes-complete = fins-complete size
Edge : Set
Edge = Node × Node
field
edges : List Edge
data Path : Node Node Set where
done : {n : Node} Path n n
step : {n₁ n₂ n₃ : Node} (n₁ , n₂) ∈ˡ edges Path n₂ n₃ Path n₁ n₃
data IsDone : {n₁ n₂} Path n₁ n₂ Set where
isDone : {n : Node} IsDone (done {n})
IsDone? : {n₁ n₂} Decidable (IsDone {n₁} {n₂})
IsDone? done = yes isDone
IsDone? (step _ _) = no (λ {()})
_++_ : {n₁ n₂ n₃} Path n₁ n₂ Path n₂ n₃ Path n₁ n₃
done ++ p = p
(step e p₁) ++ p₂ = step e (p₁ ++ p₂)
++-done : {n₁ n₂} (p : Path n₁ n₂) p ++ done p
++-done done = refl
++-done (step e∈edges p) rewrite ++-done p = refl
++-assoc : {n₁ n₂ n₃ n₄} (p₁ : Path n₁ n₂) (p₂ : Path n₂ n₃) (p₃ : Path n₃ n₄)
(p₁ ++ p₂) ++ p₃ p₁ ++ (p₂ ++ p₃)
++-assoc done p₂ p₃ = refl
++-assoc (step n₁,n∈edges p₁) p₂ p₃ rewrite ++-assoc p₁ p₂ p₃ = refl
IsDone-++ˡ : {n₁ n₂ n₃} (p₁ : Path n₁ n₂) (p₂ : Path n₂ n₃)
¬ IsDone p₁ ¬ IsDone (p₁ ++ p₂)
IsDone-++ˡ done _ done≢done = ⊥-elim (done≢done isDone)
interior : {n₁ n₂} Path n₁ n₂ List Node
interior done = []
interior (step _ done) = []
interior (step {n₂ = n₂} _ p) = n₂ interior p
interior-extend : {n₁ n₂ n₃} (p : Path n₁ n₂) (n₂,n₃∈edges : (n₂ , n₃) ∈ˡ edges)
let p' = (p ++ (step n₂,n₃∈edges done))
in (interior p' interior p) (interior p' interior p ++ˡ (n₂ []))
interior-extend done _ = inj₁ refl
interior-extend (step n₁,n₂∈edges done) n₂n₃∈edges = inj₂ refl
interior-extend {n₂ = n₂} (step {n₂ = n} n₁,n∈edges p@(step _ _)) n₂n₃∈edges
with p ++ (step n₂n₃∈edges done) | interior-extend p n₂n₃∈edges
... | done | inj₁ []≡intp rewrite sym []≡intp = inj₁ refl
... | done | inj₂ []=intp++[n₂] with () ++ˡ-conicalʳ (interior p) (n₂ []) (sym []=intp++[n₂])
... | step _ p | inj₁ IH rewrite IH = inj₁ refl
... | step _ p | inj₂ IH rewrite IH = inj₂ refl
interior-++ : {n₁ n₂ n₃} (p₁ : Path n₁ n₂) (p₂ : Path n₂ n₃)
¬ IsDone p₁ ¬ IsDone p₂
interior (p₁ ++ p₂) interior p₁ ++ˡ (n₂ interior p₂)
interior-++ done _ done≢done _ = ⊥-elim (done≢done isDone)
interior-++ _ done _ done≢done = ⊥-elim (done≢done isDone)
interior-++ (step _ done) (step _ _) _ _ = refl
interior-++ (step n₁,n∈edges p@(step n,n'∈edges p')) p₂ _ p₂≢done
rewrite interior-++ p p₂ (λ {()}) p₂≢done = refl
SimpleWalkVia : List Node Node Node Set
SimpleWalkVia ns n₁ n₂ = Σ (Path n₁ n₂) (λ p Unique (interior p) × All (_∈ˡ ns) (interior p))
SimpleWalk-extend : {n₁ n₂ n₃ ns} (w : SimpleWalkVia ns n₁ n₂) (n₂ , n₃) ∈ˡ edges All (λ ¬ n₂) (interior (proj₁ w)) n₂ ∈ˡ ns SimpleWalkVia ns n₁ n₃
SimpleWalk-extend (p , (Unique-intp , intp⊆ns)) n₂,n₃∈edges w≢n₂ n₂∈ns
with p ++ (step n₂,n₃∈edges done) | interior-extend p n₂,n₃∈edges
... | p' | inj₁ intp'≡intp rewrite sym intp'≡intp = (p' , Unique-intp , intp⊆ns)
... | p' | inj₂ intp'≡intp++[n₂]
with intp++[n₂]⊆ns ++ˡ⁺ intp⊆ns (n₂∈ns [])
rewrite sym intp'≡intp++[n₂] = (p' , (subst Unique (sym intp'≡intp++[n₂]) (Unique-append (¬Any-map sym (All¬-¬Any w≢n₂)) Unique-intp) , intp++[n₂]⊆ns))
∈ˡ-narrow : {x y : Node} {ys : List Node} x ∈ˡ (y ys) ¬ y x x ∈ˡ ys
∈ˡ-narrow (here refl) x≢y = ⊥-elim (x≢y refl)
∈ˡ-narrow (there x∈ys) _ = x∈ys
SplitSimpleWalkViaHelp : {n n₁ n₂ ns} (nⁱ : Node)
(w : SimpleWalkVia (n ns) n₁ n₂)
(p₁ : Path n₁ nⁱ) (p₂ : Path nⁱ n₂)
¬ IsDone p₁ ¬ IsDone p₂
All (_∈ˡ ns) (interior p₁)
proj₁ w p₁ ++ p₂
(Σ (SimpleWalkVia ns n₁ n × SimpleWalkVia ns n n₂) λ (w₁ , w₂) proj₁ w₁ ++ proj₁ w₂ proj₁ w) (Σ (SimpleWalkVia ns n₁ n₂) λ w' proj₁ w' proj₁ w)
SplitSimpleWalkViaHelp nⁱ w done _ done≢done _ _ _ = ⊥-elim (done≢done isDone)
SplitSimpleWalkViaHelp nⁱ w p₁ done _ done≢done _ _ = ⊥-elim (done≢done isDone)
SplitSimpleWalkViaHelp {n} {ns = ns} nⁱ w@(p , (Unique-intp , intp⊆ns)) p₁@(step _ _) p₂@(step {n₂ = nⁱ'} nⁱ,nⁱ',∈edges p₂') p₁≢done p₂≢done intp₁⊆ns p≡p₁++p₂
with intp≡intp₁++[n]++intp₂ trans (cong interior p≡p₁++p₂) (interior-++ p₁ p₂ p₁≢done p₂≢done)
with nⁱ∈n∷ns intp₂⊆n∷ns ++ˡ⁻ʳ (interior p₁) (subst (All (_∈ˡ (n ns))) intp≡intp₁++[n]++intp₂ intp⊆ns)
with nⁱ n
... | yes refl
with Unique-intp₁ Unique-++⁻ˡ (interior p₁) (subst Unique intp≡intp₁++[n]++intp₂ Unique-intp)
with (push n≢intp₂ Unique-intp₂) Unique-++⁻ʳ (interior p₁) (subst Unique intp≡intp₁++[n]++intp₂ Unique-intp)
= inj₁ (((p₁ , (Unique-intp₁ , intp₁⊆ns)) , (p₂ , (Unique-intp₂ , zipWith (uncurry ∈ˡ-narrow) (intp₂⊆n∷ns , n≢intp₂)))) , sym p≡p₁++p₂)
... | no nⁱ≢n
with p₂'
... | done
= let
-- note: copied with below branch. can't use with <- to
-- share and re-use because the termination checker loses the thread.
p₁' = (p₁ ++ (step nⁱ,nⁱ',∈edges done))
n≢nⁱ n≡nⁱ = nⁱ≢n (sym n≡nⁱ)
intp₁'=intp₁++[nⁱ] = subst (λ xs interior p₁' interior p₁ ++ˡ xs) (++ˡ-identityʳ (nⁱ [])) (interior-++ p₁ (step nⁱ,nⁱ',∈edges done) p₁≢done (λ {()}))
intp₁++[nⁱ]⊆ns = ++ˡ⁺ intp₁⊆ns (∈ˡ-narrow nⁱ∈n∷ns n≢nⁱ [])
intp₁'⊆ns = subst (All (_∈ˡ ns)) (sym intp₁'=intp₁++[nⁱ]) intp₁++[nⁱ]⊆ns
-- end shared with below branch.
Unique-intp₁++[nⁱ] = Unique-++⁻ˡ (interior p₁ ++ˡ (nⁱ [])) (subst Unique (trans intp≡intp₁++[n]++intp₂ (sym (++ˡ-assoc (interior p₁) (nⁱ []) []))) Unique-intp)
in inj₂ ((p₁ ++ (step nⁱ,nⁱ',∈edges done) , (subst Unique (sym intp₁'=intp₁++[nⁱ]) Unique-intp₁++[nⁱ] , intp₁'⊆ns)) , sym p≡p₁++p₂)
... | p₂'@(step _ _)
= let p₁' = (p₁ ++ (step nⁱ,nⁱ',∈edges done))
n≢nⁱ n≡nⁱ = nⁱ≢n (sym n≡nⁱ)
intp₁'=intp₁++[nⁱ] = subst (λ xs interior p₁' interior p₁ ++ˡ xs) (++ˡ-identityʳ (nⁱ [])) (interior-++ p₁ (step nⁱ,nⁱ',∈edges done) p₁≢done (λ {()}))
intp₁++[nⁱ]⊆ns = ++ˡ⁺ intp₁⊆ns (∈ˡ-narrow nⁱ∈n∷ns n≢nⁱ [])
intp₁'⊆ns = subst (All (_∈ˡ ns)) (sym intp₁'=intp₁++[nⁱ]) intp₁++[nⁱ]⊆ns
p≡p₁'++p₂' = trans p≡p₁++p₂ (sym (++-assoc p₁ (step nⁱ,nⁱ',∈edges done) p₂'))
in SplitSimpleWalkViaHelp nⁱ' w p₁' p₂' (IsDone-++ˡ _ _ p₁≢done) (λ {()}) intp₁'⊆ns p≡p₁'++p₂'
SplitSimpleWalkVia : {n n₁ n₂ ns} (w : SimpleWalkVia (n ns) n₁ n₂) (Σ (SimpleWalkVia ns n₁ n × SimpleWalkVia ns n n₂) λ (w₁ , w₂) proj₁ w₁ ++ proj₁ w₂ proj₁ w) (Σ (SimpleWalkVia ns n₁ n₂) λ w' proj₁ w' proj₁ w)
SplitSimpleWalkVia (done , (_ , _)) = inj₂ ((done , (empty , [])) , refl)
SplitSimpleWalkVia (step n₁,n₂∈edges done , (_ , _)) = inj₂ ((step n₁,n₂∈edges done , (empty , [])) , refl)
SplitSimpleWalkVia w@(step {n₂ = nⁱ} n₁,nⁱ∈edges p@(step _ _) , (push nⁱ≢intp Unique-intp , nⁱ∈ns intp⊆ns)) = SplitSimpleWalkViaHelp nⁱ w (step n₁,nⁱ∈edges done) p (λ {()}) (λ {()}) [] refl
open import Data.List.Membership.DecSetoid (decSetoid {A = Node} _≟_) using () renaming (_∈?_ to _∈ˡ?_)
splitFromInteriorʳ : {n₁ n₂ n} (p : Path n₁ n₂) n ∈ˡ (interior p)
Σ (Path n n₂) (λ p' ¬ IsDone p' × (Σ (List Node) λ ns interior p ns ++ˡ n interior p'))
splitFromInteriorʳ done ()
splitFromInteriorʳ (step _ done) ()
splitFromInteriorʳ (step {n₂ = n'} n₁,n'∈edges p'@(step _ _)) (here refl) = (p' , ((λ {()}) , ([] , refl)))
splitFromInteriorʳ (step {n₂ = n'} n₁,n'∈edges p'@(step _ _)) (there n∈intp')
with (p'' , (¬IsDone-p'' , (ns , intp'≡ns++intp''))) splitFromInteriorʳ p' n∈intp'
rewrite intp'≡ns++intp'' = (p'' , (¬IsDone-p'' , (n' ns , refl)))
splitFromInteriorˡ : {n₁ n₂ n} (p : Path n₁ n₂) n ∈ˡ (interior p)
Σ (Path n₁ n) (λ p' ¬ IsDone p' × (Σ (List Node) λ ns interior p interior p' ++ˡ ns))
splitFromInteriorˡ done ()
splitFromInteriorˡ (step _ done) ()
splitFromInteriorˡ p@(step {n₂ = n'} n₁,n'∈edges p'@(step _ _)) (here refl) = (step n₁,n'∈edges done , ((λ {()}) , (interior p , refl)))
splitFromInteriorˡ p@(step {n₂ = n'} n₁,n'∈edges p'@(step _ _)) (there n∈intp')
with splitFromInteriorˡ p' n∈intp'
... | (p''@(step _ _) , (¬IsDone-p'' , (ns , intp'≡intp''++ns)))
rewrite intp'≡intp''++ns
= (step n₁,n'∈edges p'' , ((λ { () }) , (ns , refl)))
... | (done , (¬IsDone-Done , _)) = ⊥-elim (¬IsDone-Done isDone)
findCycleHelp : {n₁ nⁱ n₂} (p : Path n₁ n₂) (p₁ : Path n₁ nⁱ) (p₂ : Path nⁱ n₂)
¬ IsDone p₁ Unique (interior p₁)
p p₁ ++ p₂
(Σ (SimpleWalkVia (proj₁ nodes) n₁ n₂) λ w proj₁ w p) (Σ Node (λ n Σ (SimpleWalkVia (proj₁ nodes) n n) λ w ¬ IsDone (proj₁ w)))
findCycleHelp p p₁ done ¬IsDonep₁ Unique-intp₁ p≡p₁++done rewrite ++-done p₁ = inj₁ ((p₁ , (Unique-intp₁ , tabulate (λ {x} _ nodes-complete x))) , sym p≡p₁++done)
findCycleHelp {nⁱ = nⁱ} p p₁ (step nⁱ,nⁱ'∈edges p₂') ¬IsDone-p₁ Unique-intp₁ p≡p₁++p₂
with nⁱ ∈ˡ? interior p₁
... | no nⁱ∉intp₁ =
let p₁' = p₁ ++ step nⁱ,nⁱ'∈edges done
intp₁'≡intp₁++[nⁱ] = subst (λ xs interior p₁' interior p₁ ++ˡ xs) (++ˡ-identityʳ (nⁱ [])) (interior-++ p₁ (step nⁱ,nⁱ'∈edges done) ¬IsDone-p₁ (λ {()}))
¬IsDone-p₁' = IsDone-++ˡ p₁ (step nⁱ,nⁱ'∈edges done) ¬IsDone-p₁
p≡p₁'++p₂' = trans p≡p₁++p₂ (sym (++-assoc p₁ (step nⁱ,nⁱ'∈edges done) p₂'))
Unique-intp₁' = subst Unique (sym intp₁'≡intp₁++[nⁱ]) (Unique-append nⁱ∉intp₁ Unique-intp₁)
in findCycleHelp p p₁' p₂' ¬IsDone-p₁' Unique-intp₁' p≡p₁'++p₂'
... | yes nⁱ∈intp₁
with (pᶜ , (¬IsDone-pᶜ , (ns , intp₁≡ns++intpᶜ))) splitFromInteriorʳ p₁ nⁱ∈intp₁
rewrite sym (++ˡ-assoc ns (nⁱ []) (interior pᶜ)) =
let Unique-intp₁' = subst Unique intp₁≡ns++intpᶜ Unique-intp₁
in inj₂ (nⁱ , ((pᶜ , (Unique-++⁻ʳ (ns ++ˡ nⁱ []) Unique-intp₁' , tabulate (λ {x} _ nodes-complete x))) , ¬IsDone-pᶜ))
findCycle : {n₁ n₂} (p : Path n₁ n₂) (Σ (SimpleWalkVia (proj₁ nodes) n₁ n₂) λ w proj₁ w p) (Σ Node (λ n Σ (SimpleWalkVia (proj₁ nodes) n n) λ w ¬ IsDone (proj₁ w)))
findCycle done = inj₁ ((done , (empty , [])) , refl)
findCycle (step n₁,n₂∈edges done) = inj₁ ((step n₁,n₂∈edges done , (empty , [])) , refl)
findCycle p@(step {n₂ = n'} n₁,n'∈edges p'@(step _ _)) = findCycleHelp p (step n₁,n'∈edges done) p' (λ {()}) empty refl
toSimpleWalk : {n₁ n₂} (p : Path n₁ n₂) SimpleWalkVia (proj₁ nodes) n₁ n₂
toSimpleWalk done = (done , (empty , []))
toSimpleWalk (step {n₂ = nⁱ} n₁,nⁱ∈edges p')
with toSimpleWalk p'
... | (done , _) = (step n₁,nⁱ∈edges done , (empty , []))
... | (p''@(step _ _) , (Unique-intp'' , intp''⊆nodes))
with nⁱ ∈ˡ? interior p''
... | no nⁱ∉intp'' = (step n₁,nⁱ∈edges p'' , (push (tabulate (λ { n∈intp'' refl nⁱ∉intp'' n∈intp'' })) Unique-intp'' , (nodes-complete nⁱ) intp''⊆nodes))
... | yes nⁱ∈intp''
with splitFromInteriorʳ p'' nⁱ∈intp''
... | (done , (¬IsDone=p''ʳ , (ns , intp''≡ns++intp''ʳ))) = ⊥-elim (¬IsDone=p''ʳ isDone)
... | (p''ʳ@(step _ _) , (¬IsDone=p''ʳ , (ns , intp''≡ns++intp''ʳ))) =
-- no rewrites because then I can't reason about the return value of toSimpleWalk
-- rewrite intp''≡ns++intp''ʳ
-- rewrite sym (++ˡ-assoc ns (nⁱ ∷ []) (interior p''ʳ)) =
let reassoc-intp''≡ns++intp''ʳ = subst (interior p'' ≡_) (sym (++ˡ-assoc ns (nⁱ []) (interior p''ʳ))) intp''≡ns++intp''ʳ
intp''ʳ⊆nodes = ++ˡ⁻ʳ (ns ++ˡ nⁱ []) (subst (All (_∈ˡ (proj₁ nodes))) reassoc-intp''≡ns++intp''ʳ intp''⊆nodes)
Unique-ns++intp''ʳ = subst Unique reassoc-intp''≡ns++intp''ʳ Unique-intp''
nⁱ∈p''ˡ = ∈ˡ-++⁺ʳ ns {ys = nⁱ []} (here refl)
in (step n₁,nⁱ∈edges p''ʳ , (Unique-narrow (ns ++ˡ nⁱ []) Unique-ns++intp''ʳ nⁱ∈p''ˡ , nodes-complete nⁱ intp''ʳ⊆nodes ))
toSimpleWalk-IsDone⁻ : {n₁ n₂} (p : Path n₁ n₂)
¬ IsDone p ¬ IsDone (proj₁ (toSimpleWalk p))
toSimpleWalk-IsDone⁻ done ¬IsDone-p _ = ¬IsDone-p isDone
toSimpleWalk-IsDone⁻ (step {n₂ = nⁱ} n₁,nⁱ∈edges p') _ isDone-w
with toSimpleWalk p'
... | (done , _) with () isDone-w
... | (p''@(step _ _) , (Unique-intp'' , intp''⊆nodes))
with nⁱ ∈ˡ? interior p''
... | no nⁱ∉intp'' with () isDone-w
... | yes nⁱ∈intp''
with splitFromInteriorʳ p'' nⁱ∈intp''
... | (done , (¬IsDone=p''ʳ , (ns , intp''≡ns++intp''ʳ))) = ¬IsDone=p''ʳ isDone
... | (p''ʳ@(step _ _) , (¬IsDone=p''ʳ , (ns , intp''≡ns++intp''ʳ)))
with () isDone-w
Adjacency : Set
Adjacency = (n₁ n₂ : Node) List (Path n₁ n₂)
Adjacency-update : (n₁ n₂ : Node) (List (Path n₁ n₂) List (Path n₁ n₂)) Adjacency Adjacency
Adjacency-update n₁ n₂ f adj n₁' n₂'
with n₁ n₁' | n₂ n₂'
... | yes refl | yes refl = f (adj n₁ n₂)
... | _ | _ = adj n₁' n₂'
Adjecency-append : {n₁ n₂ : Node} List (Path n₁ n₂) Adjacency Adjacency
Adjecency-append {n₁} {n₂} ps = Adjacency-update n₁ n₂ (ps ++ˡ_)
Adjacency-append-monotonic : {adj n₁ n₂ n₁' n₂'} {ps : List (Path n₁ n₂)} {p : Path n₁' n₂'} p ∈ˡ adj n₁' n₂' p ∈ˡ Adjecency-append ps adj n₁' n₂'
Adjacency-append-monotonic {adj} {n₁} {n₂} {n₁'} {n₂'} {ps} p∈adj
with n₁ n₁' | n₂ n₂'
... | yes refl | yes refl = ∈ˡ-++⁺ʳ ps p∈adj
... | yes refl | no _ = p∈adj
... | no _ | no _ = p∈adj
... | no _ | yes _ = p∈adj
adj⁰ : Adjacency
adj⁰ n₁ n₂
with n₁ n₂
... | yes refl = done []
... | no _ = []
adj⁰-done : n done ∈ˡ adj⁰ n n
adj⁰-done n
with n n
... | yes refl = here refl
... | no n≢n = ⊥-elim (n≢n refl)
seedWithEdges : (es : List Edge) ( {e} e ∈ˡ es e ∈ˡ edges) Adjacency Adjacency
seedWithEdges es e∈es⇒e∈edges adj = foldr (λ ((n₁ , n₂) , n₁n₂∈edges) Adjacency-update n₁ n₂ ((step n₁n₂∈edges done) ∷_)) adj (mapWith∈ˡ es (λ {e} e∈es (e , e∈es⇒e∈edges e∈es)))
seedWithEdges-monotonic : {n₁ n₂ es adj} (e∈es⇒e∈edges : {e} e ∈ˡ es e ∈ˡ edges) {p} p ∈ˡ adj n₁ n₂ p ∈ˡ seedWithEdges es e∈es⇒e∈edges adj n₁ n₂
seedWithEdges-monotonic {es = []} e∈es⇒e∈edges p∈adj = p∈adj
seedWithEdges-monotonic {es = (n₁ , n₂) es} e∈es⇒e∈edges p∈adj = Adjacency-append-monotonic {ps = step (e∈es⇒e∈edges (here refl)) done []} (seedWithEdges-monotonic (λ e∈es e∈es⇒e∈edges (there e∈es)) p∈adj)
e∈seedWithEdges : {n₁ n₂ es adj} (e∈es⇒e∈edges : {e} e ∈ˡ es e ∈ˡ edges) (n₁n₂∈es : (n₁ , n₂) ∈ˡ es) (step (e∈es⇒e∈edges n₁n₂∈es) done) ∈ˡ seedWithEdges es e∈es⇒e∈edges adj n₁ n₂
e∈seedWithEdges {es = []} e∈es⇒e∈edges ()
e∈seedWithEdges {es = (n₁' , n₂') es} e∈es⇒e∈edges (here refl)
with n₁' n₁' | n₂' n₂'
... | yes refl | yes refl = here refl
... | no n₁'≢n₁' | _ = ⊥-elim (n₁'≢n₁' refl)
... | _ | no n₂'≢n₂' = ⊥-elim (n₂'≢n₂' refl)
e∈seedWithEdges {n₁} {n₂} {es = (n₁' , n₂') es} {adj} e∈es⇒e∈edges (there n₁n₂∈es) = Adjacency-append-monotonic {ps = step (e∈es⇒e∈edges (here refl)) done []} (e∈seedWithEdges (λ e∈es e∈es⇒e∈edges (there e∈es)) n₁n₂∈es)
adj¹ : Adjacency
adj¹ = seedWithEdges edges (λ x x) adj⁰
adj¹-adj⁰ : {n₁ n₂ p} p ∈ˡ adj⁰ n₁ n₂ p ∈ˡ adj¹ n₁ n₂
adj¹-adj⁰ p∈adj⁰ = seedWithEdges-monotonic (λ x x) p∈adj⁰
edge∈adj¹ : {n₁ n₂} (n₁n₂∈edges : (n₁ , n₂) ∈ˡ edges) (step n₁n₂∈edges done) ∈ˡ adj¹ n₁ n₂
edge∈adj¹ = e∈seedWithEdges (λ x x)
through : Node Adjacency Adjacency
through n adj n₁ n₂ = cartesianProductWith _++_ (adj n₁ n) (adj n n₂) ++ˡ adj n₁ n₂
through-monotonic : adj n {n₁ n₂ p} p ∈ˡ adj n₁ n₂ p ∈ˡ (through n adj) n₁ n₂
through-monotonic adj n p∈adjn₁n₂ = ∈ˡ-++⁺ʳ _ p∈adjn₁n₂
through-++ : adj n {n₁ n₂} {p₁ : Path n₁ n} {p₂ : Path n n₂} p₁ ∈ˡ adj n₁ n p₂ ∈ˡ adj n n₂ (p₁ ++ p₂) ∈ˡ through n adj n₁ n₂
through-++ adj n p₁∈adj p₂∈adj = ∈ˡ-++⁺ˡ (∈ˡ-cartesianProductWith⁺ _++_ p₁∈adj p₂∈adj)
throughAll : List Node Adjacency
throughAll = foldr through adj¹
throughAll-adj₁ : {n₁ n₂ p} ns p ∈ˡ adj¹ n₁ n₂ p ∈ˡ throughAll ns n₁ n₂
throughAll-adj₁ [] p∈adj¹ = p∈adj¹
throughAll-adj₁ (n ns) p∈adj¹ = through-monotonic (throughAll ns) n (throughAll-adj₁ ns p∈adj¹)
paths-throughAll : {n₁ n₂ : Node} (ns : List Node) (w : SimpleWalkVia ns n₁ n₂) proj₁ w ∈ˡ throughAll ns n₁ n₂
paths-throughAll {n₁} [] (done , (_ , _)) = adj¹-adj⁰ (adj⁰-done n₁)
paths-throughAll {n₁} [] (step e∈edges done , (_ , _)) = edge∈adj¹ e∈edges
paths-throughAll {n₁} [] (step _ (step _ _) , (_ , (() _)))
paths-throughAll (n ns) w
with SplitSimpleWalkVia w
... | inj₁ ((w₁ , w₂) , w₁++w₂≡w) rewrite sym w₁++w₂≡w = through-++ (throughAll ns) n (paths-throughAll ns w₁) (paths-throughAll ns w₂)
... | inj₂ (w' , w'≡w) rewrite sym w'≡w = through-monotonic (throughAll ns) n (paths-throughAll ns w')
adj : Adjacency
adj = throughAll (proj₁ nodes)
PathExists : Node Node Set
PathExists n₁ n₂ = Path n₁ n₂
PathExists? : Decidable² PathExists
PathExists? n₁ n₂
with allSimplePathsNoted paths-throughAll {n₁ = n₁} {n₂ = n₂} (proj₁ nodes)
with adj n₁ n₂
... | [] = no (λ p let w = toSimpleWalk p in ¬Any[] (allSimplePathsNoted w))
... | (p ps) = yes p
NoCycles : Set
NoCycles = {n} (p : Path n n) IsDone p
NoCycles? : Dec NoCycles
NoCycles? with any? (λ n any? (Decidable-¬ IsDone?) (adj n n)) (proj₁ nodes)
... | yes existsCycle =
no (λ p,IsDonep let (n , n,n-cycle) = satisfied existsCycle in
let (p , ¬IsDone-p) = satisfied n,n-cycle in
¬IsDone-p (p,IsDonep p))
... | no noCycles =
yes (λ { done isDone
; p@(step {n₁ = n} _ _)
let w = toSimpleWalk p in
let ¬IsDone-w = toSimpleWalk-IsDone⁻ p (λ {()}) in
let w∈adj = paths-throughAll (proj₁ nodes) w in
⊥-elim (noCycles (lose (nodes-complete n) (lose w∈adj ¬IsDone-w)))
})
NoCycles⇒adj-complete : NoCycles {n₁ n₂} {p : Path n₁ n₂} p ∈ˡ adj n₁ n₂
NoCycles⇒adj-complete noCycles {n₁} {n₂} {p}
with findCycle p
... | inj₁ (w , w≡p) rewrite sym w≡p = paths-throughAll (proj₁ nodes) w
... | inj₂ (nᶜ , (wᶜ , wᶜ≢done)) = ⊥-elim (wᶜ≢done (noCycles (proj₁ wᶜ)))
Is- : Node Set
Is- n = All (PathExists n) (proj₁ nodes)
Is-⊥ : Node Set
Is-⊥ n = All (λ n' PathExists n' n) (proj₁ nodes)
Has- : Set
Has- = Any Is- (proj₁ nodes)
Has-T? : Dec Has-
Has-T? = findUniversal (proj₁ nodes) PathExists?
Has-⊥ : Set
Has-⊥ = Any Is-⊥ (proj₁ nodes)
Has-⊥? : Dec Has-⊥
Has-⊥? = findUniversal (proj₁ nodes) (λ n₁ n₂ PathExists? n₂ n₁)

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open import Lattice
module Lattice.ExtendBelow {a} (A : Set a)
{_≈₁_ : A A Set a} {_⊔₁_ : A A A} {_⊓₁_ : A A A}
{{lA : IsLattice A _≈₁_ _⊔₁_ _⊓₁_}} where
open import Equivalence
open import Showable using (Showable; show)
open import Relation.Binary.Definitions using (Decidable)
open import Relation.Binary.PropositionalEquality using (refl)
open import Relation.Nullary using (Dec; ¬_; yes; no)
open IsLattice lA using ()
renaming ( ≈-equiv to ≈₁-equiv
; ≈-⊔-cong to ≈₁-⊔₁-cong
; ⊔-assoc to ⊔₁-assoc; ⊔-comm to ⊔₁-comm; ⊔-idemp to ⊔₁-idemp
; ≈-⊓-cong to ≈₁-⊓₁-cong
; ⊓-assoc to ⊓₁-assoc; ⊓-comm to ⊓₁-comm; ⊓-idemp to ⊓₁-idemp
; absorb-⊔-⊓ to absorb-⊔₁-⊓₁; absorb-⊓-⊔ to absorb-⊓₁-⊔₁
)
open IsEquivalence ≈₁-equiv using ()
renaming (≈-refl to ≈₁-refl; ≈-sym to ≈₁-sym; ≈-trans to ≈₁-trans)
data ExtendBelow : Set a where
[_] : A ExtendBelow
: ExtendBelow
instance
showable : {{ showableA : Showable A }} Showable ExtendBelow
showable = record
{ show = (λ
{ ""
; [ a ] show a
})
}
data _≈_ : ExtendBelow ExtendBelow Set a where
≈-⊥-⊥ :
≈-lift : {x y : A} x ≈₁ y [ x ] [ y ]
≈-refl : {ab : ExtendBelow} ab ab
≈-refl {} = ≈-⊥-⊥
≈-refl {[ x ]} = ≈-lift ≈₁-refl
≈-sym : {ab₁ ab₂ : ExtendBelow} ab₁ ab₂ ab₂ ab₁
≈-sym ≈-⊥-⊥ = ≈-⊥-⊥
≈-sym (≈-lift x≈₁y) = ≈-lift (≈₁-sym x≈₁y)
≈-trans : {ab₁ ab₂ ab₃ : ExtendBelow} ab₁ ab₂ ab₂ ab₃ ab₁ ab₃
≈-trans ≈-⊥-⊥ ≈-⊥-⊥ = ≈-⊥-⊥
≈-trans (≈-lift a₁≈a₂) (≈-lift a₂≈a₃) = ≈-lift (≈₁-trans a₁≈a₂ a₂≈a₃)
instance
≈-equiv : IsEquivalence ExtendBelow _≈_
≈-equiv = record
{ ≈-refl = ≈-refl
; ≈-sym = ≈-sym
; ≈-trans = ≈-trans
}
_⊔_ : ExtendBelow ExtendBelow ExtendBelow
_⊔_ x = x
_⊔_ [ a₁ ] = [ a₁ ]
_⊔_ [ a₁ ] [ a₂ ] = [ a₁ ⊔₁ a₂ ]
_⊓_ : ExtendBelow ExtendBelow ExtendBelow
_⊓_ x =
_⊓_ [ _ ] =
_⊓_ [ a₁ ] [ a₂ ] = [ a₁ ⊓₁ a₂ ]
≈-⊔-cong : {x₁ x₂ x₃ x₄} x₁ x₂ x₃ x₄
(x₁ x₃) (x₂ x₄)
≈-⊔-cong .{} .{} {x₃} {x₄} ≈-⊥-⊥ [a₃]≈[a₄] = [a₃]≈[a₄]
≈-⊔-cong {x₁ = [ a₁ ]} {x₂ = [ a₂ ]} .{} .{} [a₁]≈[a₂] ≈-⊥-⊥ = [a₁]≈[a₂]
≈-⊔-cong {x₁ = [ a₁ ]} {x₂ = [ a₂ ]} {x₃ = [ a₃ ]} {x₄ = [ a₄ ]} (≈-lift a₁≈a₂) (≈-lift a₃≈a₄) = ≈-lift (≈₁-⊔₁-cong a₁≈a₂ a₃≈a₄)
⊔-assoc : (x₁ x₂ x₃ : ExtendBelow) ((x₁ x₂) x₃) (x₁ (x₂ x₃))
⊔-assoc x₁ x₂ = ≈-refl
⊔-assoc [ a₁ ] x₂ = ≈-refl
⊔-assoc [ a₁ ] [ a₂ ] = ≈-refl
⊔-assoc [ a₁ ] [ a₂ ] [ a₃ ] = ≈-lift (⊔₁-assoc a₁ a₂ a₃)
⊔-comm : (x₁ x₂ : ExtendBelow) (x₁ x₂) (x₂ x₁)
⊔-comm = ≈-refl
⊔-comm [ a₂ ] = ≈-refl
⊔-comm [ a₁ ] = ≈-refl
⊔-comm [ a₁ ] [ a₂ ] = ≈-lift (⊔₁-comm a₁ a₂)
⊔-idemp : (x : ExtendBelow) (x x) x
⊔-idemp = ≈-refl
⊔-idemp [ a ] = ≈-lift (⊔₁-idemp a)
≈-⊓-cong : {x₁ x₂ x₃ x₄} x₁ x₂ x₃ x₄
(x₁ x₃) (x₂ x₄)
≈-⊓-cong .{} .{} {x₃} {x₄} ≈-⊥-⊥ [a₃]≈[a₄] = ≈-⊥-⊥
≈-⊓-cong {x₁ = [ a₁ ]} {x₂ = [ a₂ ]} .{} .{} [a₁]≈[a₂] ≈-⊥-⊥ = ≈-⊥-⊥
≈-⊓-cong {x₁ = [ a₁ ]} {x₂ = [ a₂ ]} {x₃ = [ a₃ ]} {x₄ = [ a₄ ]} (≈-lift a₁≈a₂) (≈-lift a₃≈a₄) = ≈-lift (≈₁-⊓₁-cong a₁≈a₂ a₃≈a₄)
⊓-assoc : (x₁ x₂ x₃ : ExtendBelow) ((x₁ x₂) x₃) (x₁ (x₂ x₃))
⊓-assoc x₁ x₂ = ≈-refl
⊓-assoc [ a₁ ] x₂ = ≈-refl
⊓-assoc [ a₁ ] [ a₂ ] = ≈-refl
⊓-assoc [ a₁ ] [ a₂ ] [ a₃ ] = ≈-lift (⊓₁-assoc a₁ a₂ a₃)
⊓-comm : (x₁ x₂ : ExtendBelow) (x₁ x₂) (x₂ x₁)
⊓-comm = ≈-refl
⊓-comm [ a₂ ] = ≈-refl
⊓-comm [ a₁ ] = ≈-refl
⊓-comm [ a₁ ] [ a₂ ] = ≈-lift (⊓₁-comm a₁ a₂)
⊓-idemp : (x : ExtendBelow) (x x) x
⊓-idemp = ≈-refl
⊓-idemp [ a ] = ≈-lift (⊓₁-idemp a)
absorb-⊔-⊓ : (x₁ x₂ : ExtendBelow) (x₁ (x₁ x₂)) x₁
absorb-⊔-⊓ = ≈-refl
absorb-⊔-⊓ [ a₂ ] = ≈-refl
absorb-⊔-⊓ [ a₁ ] = ≈-refl
absorb-⊔-⊓ [ a₁ ] [ a₂ ] = ≈-lift (absorb-⊔₁-⊓₁ a₁ a₂)
absorb-⊓-⊔ : (x₁ x₂ : ExtendBelow) (x₁ (x₁ x₂)) x₁
absorb-⊓-⊔ = ≈-refl
absorb-⊓-⊔ [ a₂ ] = ≈-refl
absorb-⊓-⊔ [ a₁ ] = ⊓-idemp [ a₁ ]
absorb-⊓-⊔ [ a₁ ] [ a₂ ] = ≈-lift (absorb-⊓₁-⊔₁ a₁ a₂)
instance
isJoinSemilattice : IsSemilattice ExtendBelow _≈_ _⊔_
isJoinSemilattice = record
{ ≈-equiv = ≈-equiv
; ≈-⊔-cong = ≈-⊔-cong
; ⊔-assoc = ⊔-assoc
; ⊔-comm = ⊔-comm
; ⊔-idemp = ⊔-idemp
}
isMeetSemilattice : IsSemilattice ExtendBelow _≈_ _⊓_
isMeetSemilattice = record
{ ≈-equiv = ≈-equiv
; ≈-⊔-cong = ≈-⊓-cong
; ⊔-assoc = ⊓-assoc
; ⊔-comm = ⊓-comm
; ⊔-idemp = ⊓-idemp
}
isLattice : IsLattice ExtendBelow _≈_ _⊔_ _⊓_
isLattice = record
{ joinSemilattice = isJoinSemilattice
; meetSemilattice = isMeetSemilattice
; absorb-⊔-⊓ = absorb-⊔-⊓
; absorb-⊓-⊔ = absorb-⊓-⊔
}
module _ {{≈₁-Decidable : IsDecidable _≈₁_}} where
open IsDecidable ≈₁-Decidable using () renaming (R-dec to ≈₁-dec)
≈-dec : Decidable _≈_
≈-dec = yes ≈-⊥-⊥
≈-dec [ a₁ ] [ a₂ ]
with ≈₁-dec a₁ a₂
... | yes a₁≈a₂ = yes (≈-lift a₁≈a₂)
... | no a₁̷≈a₂ = no (λ { (≈-lift a₁≈a₂) a₁̷≈a₂ a₁≈a₂ })
≈-dec [ _ ] = no (λ ())
≈-dec [ _ ] = no (λ ())
instance
≈-Decidable : IsDecidable _≈_
≈-Decidable = record { R-dec = ≈-dec }

513
Lattice/FiniteMap.agda
View File

@@ -3,16 +3,28 @@ open import Relation.Binary.PropositionalEquality as Eq
using (_≡_;refl; sym; trans; cong; subst)
open import Agda.Primitive using (Level) renaming (_⊔_ to _⊔_)
open import Data.List using (List; _∷_; [])
open import Data.Unit using ()
module Lattice.FiniteMap {a b : Level} {A : Set a} {B : Set b}
{_≈₂_ : B B Set b}
module Lattice.FiniteMap (A : Set) (B : Set)
{_≈₂_ : B B Set}
{_⊔₂_ : B B B} {_⊓₂_ : B B B}
(≡-dec-A : IsDecidable (_≡_ {a} {A}))
(lB : IsLattice B _≈₂_ _⊔₂_ _⊓₂_) where
{{≡-Decidable-A : IsDecidable {_} {A} _≡_}}
{{lB : IsLattice B _≈₂_ _⊔₂_ _⊓₂_}} (ks : List A) where
open IsLattice lB using () renaming (_≼_ to _≼₂_)
open import Lattice.Map ≡-dec-A lB as Map
using (Map; ⊔-equal-keys; ⊓-equal-keys)
open import Lattice.Map A B _ as Map
using
( Map
; ⊔-equal-keys
; ⊓-equal-keys
; subset-impl
; Map-functional
; Expr-Provenance
; Expr-Provenance-≡
; `_; __; _∩_
; in₁; in₂; bothᵘ; single
; ⊔-combines
)
renaming
( _≈_ to _≈ᵐ_
; _⊔_ to _⊔ᵐ_
@@ -28,7 +40,7 @@ open import Lattice.Map ≡-dec-A lB as Map
; ⊓-idemp to ⊓ᵐ-idemp
; absorb-⊔-⊓ to absorb-⊔ᵐ-⊓ᵐ
; absorb-⊓-⊔ to absorb-⊓ᵐ-⊔ᵐ
; ≈-dec to ≈ᵐ-dec
; ≈-Decidable to ≈ᵐ-Decidable
; _[_] to _[_]ᵐ
; []-∈ to []ᵐ-∈
; m₁≼m₂⇒m₁[k]≼m₂[k] to m₁≼m₂⇒m₁[k]ᵐ≼m₂[k]ᵐ
@@ -46,17 +58,24 @@ open import Lattice.Map ≡-dec-A lB as Map
; _≼_ to _≼ᵐ_
; ∈k-dec to ∈k-decᵐ
)
open import Data.Empty using (⊥-elim)
open import Data.List using (List; length; []; _∷_; map)
open import Data.List.Membership.Propositional using () renaming (_∈_ to _∈ˡ_)
open import Data.Product using (_×_; _,_; Σ; proj₁ ; proj₂)
open import Data.List.Properties using (∷-injectiveʳ)
open import Data.List.Relation.Unary.All using (All)
open import Data.List.Relation.Unary.Any using (Any; here; there)
open import Data.Nat using ()
open import Data.Product using (_×_; _,_; Σ; proj₁; proj₂)
open import Equivalence
open import Function using (_∘_)
open import Relation.Nullary using (¬_; Dec; yes; no)
open import Utils using (Pairwise; _∷_; [])
open import Data.Empty using (⊥-elim)
open import Utils using (Pairwise; _∷_; []; Unique; push; empty; All¬-¬Any)
open import Showable using (Showable; show)
open import Isomorphism using (IsInverseˡ; IsInverseʳ)
open import Chain using (Height)
module WithKeys (ks : List A) where
FiniteMap : Set (a ⊔ℓ b)
private module WithKeys (ks : List A) where
FiniteMap : Set
FiniteMap = Σ Map (λ m Map.keys m ks)
instance
@@ -64,11 +83,15 @@ module WithKeys (ks : List A) where
Showable FiniteMap
showable = record { show = λ (m₁ , _) show m₁ }
_≈_ : FiniteMap FiniteMap Set (a ⊔ℓ b)
_≈_ : FiniteMap FiniteMap Set
_≈_ (m₁ , _) (m₂ , _) = m₁ ≈ᵐ m₂
≈₂-dec⇒≈-dec : IsDecidable _≈₂_ IsDecidable _≈_
≈₂-dec⇒≈-dec ≈₂-dec fm₁ fm₂ = ≈ᵐ-dec ≈₂-dec (proj₁ fm₁) (proj₁ fm₂)
instance
≈-Decidable : {{ IsDecidable _≈₂_ }} IsDecidable _≈_
≈-Decidable {{≈₂-Decidable}} = record
{ R-dec = λ fm₁ fm₂ IsDecidable.R-dec (≈ᵐ-Decidable {{≈₂-Decidable}})
(proj₁ fm₁) (proj₁ fm₂)
}
_⊔_ : FiniteMap FiniteMap FiniteMap
_⊔_ (m₁ , km₁≡ks) (m₂ , km₂≡ks) =
@@ -84,10 +107,10 @@ module WithKeys (ks : List A) where
km₁≡ks
)
_∈_ : A × B FiniteMap Set (a ⊔ℓ b)
_∈_ : A × B FiniteMap Set
_∈_ k,v (m₁ , _) = k,v ∈ˡ (proj₁ m₁)
_∈k_ : A FiniteMap Set a
_∈k_ : A FiniteMap Set
_∈k_ k (m₁ , _) = k ∈ˡ (keysᵐ m₁)
open Map using (forget) public
@@ -120,46 +143,48 @@ module WithKeys (ks : List A) where
λ {(m₁ , _)} {(m₂ , _)} {(m₃ , _)}
IsEquivalence.≈-trans ≈ᵐ-equiv {m₁} {m₂} {m₃}
}
open IsEquivalence ≈-equiv public
isUnionSemilattice : IsSemilattice FiniteMap _≈_ _⊔_
isUnionSemilattice = record
{ ≈-equiv = ≈-equiv
; ≈-⊔-cong =
λ {(m₁ , _)} {(m₂ , _)} {(m₃ , _)} {(m₄ , _)} m₁≈m₂ m₃≈m₄
≈ᵐ-⊔ᵐ-cong {m₁} {m₂} {m₃} {m₄} m₁≈m₂ m₃≈m₄
; ⊔-assoc = λ (m₁ , _) (m₂ , _) (m , _) ⊔ᵐ-assoc m₁ m₂ m₃
; ⊔-comm = λ (m₁ , _) (m₂ , _) ⊔ᵐ-comm m₁ m₂
; ⊔-idemp = λ (m , _) ⊔ᵐ-idemp m
}
instance
isUnionSemilattice : IsSemilattice FiniteMap _≈_ _⊔_
isUnionSemilattice = record
{ ≈-equiv = ≈-equiv
; ≈-⊔-cong =
λ {(m₁ , _)} {(m₂ , _)} {(m₃ , _)} {(m₄ , _)} m₁≈m₂ m₃≈m₄
≈ᵐ-⊔ᵐ-cong {m₁} {m} {m₃} {m₄} m₁m₂ m₃≈m₄
; ⊔-assoc = λ (m₁ , _) (m₂ , _) (m₃ , _) ⊔ᵐ-assoc m₁ m₂ m₃
; ⊔-comm = λ (m , _) (m₂ , _) ⊔ᵐ-comm m₁ m
; ⊔-idemp = λ (m , _) ⊔ᵐ-idemp m
}
isIntersectSemilattice : IsSemilattice FiniteMap _≈_ _⊓_
isIntersectSemilattice = record
{ ≈-equiv = ≈-equiv
; ≈-⊔-cong =
λ {(m₁ , _)} {(m₂ , _)} {(m₃ , _)} {(m₄ , _)} m₁≈m₂ m₃≈m₄
≈ᵐ-⊓ᵐ-cong {m₁} {m₂} {m₃} {m₄} m₁≈m₂ m₃≈m₄
; ⊔-assoc = λ (m₁ , _) (m₂ , _) (m₃ , _) ⊓ᵐ-assoc m₁ m₂ m₃
; ⊔-comm = λ (m₁ , _) (m₂ , _) ⊓ᵐ-comm m₁ m₂
; ⊔-idemp = λ (m , _) ⊓ᵐ-idemp m
}
isIntersectSemilattice : IsSemilattice FiniteMap _≈_ _⊓_
isIntersectSemilattice = record
{ ≈-equiv = ≈-equiv
; ≈-⊔-cong =
λ {(m₁ , _)} {(m₂ , _)} {(m₃ , _)} {(m₄ , _)} m₁≈m₂ m₃≈m₄
≈ᵐ-⊓ᵐ-cong {m₁} {m₂} {m₃} {m₄} m₁≈m₂ m₃≈m₄
; ⊔-assoc = λ (m₁ , _) (m₂ , _) (m₃ , _) ⊓ᵐ-assoc m₁ m₂ m₃
; ⊔-comm = λ (m₁ , _) (m₂ , _) ⊓ᵐ-comm m₁ m₂
; ⊔-idemp = λ (m , _) ⊓ᵐ-idemp m
}
isLattice : IsLattice FiniteMap _≈_ _⊔_ _⊓_
isLattice = record
{ joinSemilattice = isUnionSemilattice
; meetSemilattice = isIntersectSemilattice
; absorb-⊔-⊓ = λ (m₁ , _) (m₂ , _) absorb-⊔ᵐ-⊓ᵐ m₁ m₂
; absorb-⊓-⊔ = λ (m₁ , _) (m₂ , _) absorb-⊓ᵐ-⊔ᵐ m₁ m₂
}
isLattice : IsLattice FiniteMap _≈_ _⊔_ _⊓_
isLattice = record
{ joinSemilattice = isUnionSemilattice
; meetSemilattice = isIntersectSemilattice
; absorb-⊔-⊓ = λ (m₁ , _) (m₂ , _) absorb-⊔ᵐ-⊓ᵐ m₁ m₂
; absorb-⊓-⊔ = λ (m₁ , _) (m₂ , _) absorb-⊓ᵐ-⊔ᵐ m₁ m₂
}
open IsLattice isLattice using (_≼_; ⊔-Monotonicˡ; ⊔-Monotonicʳ) public
lattice : Lattice FiniteMap
lattice = record
{ _≈_ = _≈_
; _⊔_ = _⊔_
; _⊓_ = _⊓_
; isLattice = isLattice
}
lattice : Lattice FiniteMap
lattice = record
{ _≈_ = _≈_
; _⊔_ = _⊔_
; _⊓_ = _⊓_
; isLattice = isLattice
}
open IsLattice isLattice using (_≼_; ⊔-idemp; ⊔-Monotonicˡ; ⊔-Monotonicʳ) public
m₁≼m₂⇒m₁[k]≼m₂[k] : (fm₁ fm₂ : FiniteMap) {k : A} {v₁ v₂ : B}
fm₁ fm₂ (k , v₁) fm₁ (k , v₂) fm₂ v₁ ≼₂ v₂
@@ -173,7 +198,7 @@ module WithKeys (ks : List A) where
module GeneralizedUpdate
{l} {L : Set l}
{_≈ˡ_ : L L Set l} {_⊔ˡ_ : L L L} {_⊓ˡ_ : L L L}
(lL : IsLattice L _≈ˡ_ _⊔ˡ_ _⊓ˡ_)
{{lL : IsLattice L _≈ˡ_ _⊔ˡ_ _⊓ˡ_}}
(f : L FiniteMap) (f-Monotonic : Monotonic (IsLattice._≼_ lL) _≼_ f)
(g : A L B) (g-Monotonicʳ : k Monotonic (IsLattice._≼_ lL) _≼₂_ (g k))
(ks : List A) where
@@ -187,7 +212,7 @@ module WithKeys (ks : List A) where
f' l = (f l) updating ks via (updater l)
f'-Monotonic : Monotonic _≼ˡ_ _≼_ f'
f'-Monotonic {l₁} {l₂} l₁≼l₂ = f'-Monotonicᵐ lL (proj₁ f) f-Monotonic g g-Monotonicʳ ks l₁≼l₂
f'-Monotonic {l₁} {l₂} l₁≼l₂ = f'-Monotonicᵐ (proj₁ f) f-Monotonic g g-Monotonicʳ ks l₁≼l₂
f'-∈k-forward : {k l} k ∈k (f l) k ∈k (f' l)
f'-∈k-forward {k} {l} = updatingᵐ-via-∈k-forward (proj₁ (f l)) ks (updater l)
@@ -229,4 +254,382 @@ module WithKeys (ks : List A) where
... | yes k∈km₁ | no k∉km₂ = ⊥-elim (∈k-exclusive fm₁ fm₂ (k∈km₁ , k∉km₂))
... | no k∉km₁ | yes k∈km₂ = ⊥-elim (∈k-exclusive fm₂ fm₁ (k∈km₂ , k∉km₁))
open WithKeys public
private
_⊆ᵐ_ : {ks₁ ks₂ : List A} WithKeys.FiniteMap ks₁ WithKeys.FiniteMap ks₂ Set
_⊆ᵐ_ fm₁ fm₂ = subset-impl (proj₁ (proj₁ fm₁)) (proj₁ (proj₁ fm₂))
_∈ᵐ_ : {ks : List A} A × B WithKeys.FiniteMap ks Set
_∈ᵐ_ {ks} = WithKeys._∈_ ks
FromBothMaps : (k : A) (v : B) {ks : List A} (fm₁ fm₂ : WithKeys.FiniteMap ks) Set
FromBothMaps k v fm₁ fm₂ =
Σ (B × B)
(λ (v₁ , v₂) ( (v v₁ ⊔₂ v₂) × ((k , v₁) ∈ᵐ fm₁ × (k , v₂) ∈ᵐ fm₂)))
Provenance-union : {ks : List A} (fm₁ fm₂ : WithKeys.FiniteMap ks) {k : A} {v : B}
(k , v) ∈ᵐ (WithKeys._⊔_ ks fm₁ fm₂) FromBothMaps k v fm₁ fm₂
Provenance-union fm₁@(m₁ , ks₁≡ks) fm₂@(m₂ , ks₂≡ks) {k} {v} k,v∈fm₁fm₂
with Expr-Provenance-≡ ((` m₁) (` m₂)) k,v∈fm₁fm₂
... | in (single k,v∈m₁) k∉km₂
with k∈km₁ (WithKeys.forget k,v∈m₁)
rewrite trans ks₁≡ks (sym ks₂≡ks) =
⊥-elim (k∉km₂ k∈km₁)
... | in k∉km₁ (single k,v∈m₂)
with k∈km₂ (WithKeys.forget k,v∈m₂)
rewrite trans ks₁≡ks (sym ks₂≡ks) =
⊥-elim (k∉km₁ k∈km₂)
... | bothᵘ {v₁} {v₂} (single k,v₁∈m₁) (single k,v₂∈m₂) =
((v₁ , v₂) , (refl , (k,v₁∈m₁ , k,v₂∈m₂)))
private module IterProdIsomorphism where
open WithKeys
open import Data.Unit using (tt)
open import Lattice.Unit using ()
renaming
( _≈_ to _≈ᵘ_
; _⊔_ to _⊔ᵘ_
; _⊓_ to _⊓ᵘ_
; ≈-Decidable to ≈ᵘ-Decidable
; isLattice to isLatticeᵘ
; ≈-equiv to ≈ᵘ-equiv
; fixedHeight to fixedHeightᵘ
)
open import Lattice.IterProd B _
as IP
using (IterProd)
open IsLattice lB using ()
renaming
( ≈-trans to ≈₂-trans
; ≈-sym to ≈₂-sym
; FixedHeight to FixedHeight₂
)
from : {ks : List A} FiniteMap ks IterProd (length ks)
from {[]} (([] , _) , _) = tt
from {k ks'} (((k' , v) fm' , push _ uks') , refl) =
(v , from ((fm' , uks'), refl))
to : {ks : List A} Unique ks IterProd (length ks) FiniteMap ks
to {[]} _ = (([] , empty) , refl)
to {k ks'} (push k≢ks' uks') (v , rest) =
let
((fm' , ufm') , fm'≡ks') = to uks' rest
-- This would be easier if we pattern matched on the equiality proof
-- to get refl, but that makes it harder to reason about 'to' when
-- the arguments are not known to be refl.
k≢fm' = subst (λ ks All (λ k' ¬ k k') ks) (sym fm'≡ks') k≢ks'
kvs≡ks = cong (k ∷_) fm'≡ks'
in
(((k , v) fm' , push k≢fm' ufm') , kvs≡ks)
_≈ⁱᵖ_ : {n : } IterProd n IterProd n Set
_≈ⁱᵖ_ {n} = IP._≈_ {n}
_⊔ⁱᵖ_ : {ks : List A}
IterProd (length ks) IterProd (length ks) IterProd (length ks)
_⊔ⁱᵖ_ {ks} = IP._⊔_ {length ks}
to-build : {b : B} {ks : List A} (uks : Unique ks)
let fm = to uks (IP.build b tt (length ks))
in (k : A) (v : B) (k , v) ∈ᵐ fm v b
to-build {b} {k ks'} (push _ uks') k v (here refl) = refl
to-build {b} {k ks'} (push _ uks') k' v (there k',v∈m') =
to-build {ks = ks'} uks' k' v k',v∈m'
-- The left inverse is: from (to x) = x
from-to-inverseˡ : {ks : List A} (uks : Unique ks)
IsInverseˡ (_≈_ ks) (_≈ⁱᵖ_ {length ks})
(from {ks}) (to {ks} uks)
from-to-inverseˡ {[]} _ _ = IsEquivalence.≈-refl (IP.≈-equiv {0})
from-to-inverseˡ {k ks'} (push k≢ks' uks') (v , rest)
with ((fm' , ufm') , refl) to uks' rest in p rewrite sym p =
(IsLattice.≈-refl lB , from-to-inverseˡ {ks'} uks' rest)
-- the rewrite here is needed because the IH is in terms of `to uks' rest`,
-- but we end up with the 'unpacked' form (fm', ...). So, put it back
-- in the 'packed' form after we've performed enough inspection
-- to know we take the cons branch of `to`.
-- The map has its own uniqueness proof, but the call to 'to' needs a standalone
-- uniqueness proof too. Work with both proofs as needed to thread things through.
--
-- The right inverse is: to (from x) = x
from-to-inverseʳ : {ks : List A} (uks : Unique ks)
IsInverseʳ (_≈_ ks) (_≈ⁱᵖ_ {length ks})
(from {ks}) (to {ks} uks)
from-to-inverseʳ {[]} _ (([] , empty) , kvs≡ks) rewrite kvs≡ks =
( (λ k v ())
, (λ k v ())
)
from-to-inverseʳ {k ks'} uks@(push _ uks'₁) fm₁@(((k , v) fm'₁ , push _ uks'₂) , refl)
with to uks'₁ (from ((fm'₁ , uks'₂) , refl))
| from-to-inverseʳ {ks'} uks'₁ ((fm'₁ , uks'₂) , refl)
... | ((fm'₂ , ufm'₂) , _)
| (fm'₂⊆fm'₁ , fm'₁⊆fm'₂) = (m₂⊆m₁ , m₁⊆m₂)
where
kvs₁ = (k , v) fm'₁
kvs₂ = (k , v) fm'₂
m₁⊆m₂ : subset-impl kvs₁ kvs₂
m₁⊆m₂ k' v' (here refl) =
(v' , (IsLattice.≈-refl lB , here refl))
m₁⊆m₂ k' v' (there k',v'∈fm'₁) =
let (v'' , (v'≈v'' , k',v''∈fm'₂)) =
fm'₁⊆fm'₂ k' v' k',v'∈fm'₁
in (v'' , (v'≈v'' , there k',v''∈fm'₂))
m₂⊆m₁ : subset-impl kvs₂ kvs₁
m₂⊆m₁ k' v' (here refl) =
(v' , (IsLattice.≈-refl lB , here refl))
m₂⊆m₁ k' v' (there k',v'∈fm'₂) =
let (v'' , (v'≈v'' , k',v''∈fm'₁)) =
fm'₂⊆fm'₁ k' v' k',v'∈fm'₂
in (v'' , (v'≈v'' , there k',v''∈fm'₁))
private
first-key-in-map : {k : A} {ks : List A} (fm : FiniteMap (k ks))
Σ B (λ v (k , v) ∈ᵐ fm)
first-key-in-map (((k , v) _ , _) , refl) = (v , here refl)
from-first-value : {k : A} {ks : List A} (fm : FiniteMap (k ks))
proj₁ (from fm) proj₁ (first-key-in-map fm)
from-first-value {k} {ks} (((k , v) _ , push _ _) , refl) = refl
-- We need pop because reasoning about two distinct 'refl' pattern
-- matches is giving us unification errors. So, stash the 'refl' pattern
-- matching into a helper functions, and write solutions in terms
-- of that.
pop : {k : A} {ks : List A} FiniteMap (k ks) FiniteMap ks
pop (((_ fm') , push _ ufm') , refl) = ((fm' , ufm') , refl)
pop-≈ : {k : A} {ks : List A} (fm₁ fm₂ : FiniteMap (k ks))
_≈_ _ fm₁ fm₂ _≈_ _ (pop fm₁) (pop fm₂)
pop-≈ {k} {ks} fm₁ fm₂ (fm₁⊆fm₂ , fm₂⊆fm₁) =
(narrow fm₁⊆fm₂ , narrow fm₂⊆fm₁)
where
narrow₁ : {fm₁ fm₂ : FiniteMap (k ks)}
fm₁ ⊆ᵐ fm₂ pop fm₁ ⊆ᵐ fm₂
narrow₁ {(_ _ , push _ _) , refl} kvs₁⊆kvs₂ k' v' k',v'∈fm'₁ =
kvs₁⊆kvs₂ k' v' (there k',v'∈fm'₁)
narrow₂ : {fm₁ : FiniteMap ks} {fm₂ : FiniteMap (k ks)}
fm₁ ⊆ᵐ fm₂ fm₁ ⊆ᵐ pop fm₂
narrow₂ {fm₁} {fm₂ = (_ fm'₂ , push k≢ks _) , kvs≡ks@refl} kvs₁⊆kvs₂ k' v' k',v'∈fm'₁
with kvs₁⊆kvs₂ k' v' k',v'∈fm'₁
... | (v'' , (v'≈v'' , here refl)) rewrite sym (proj₂ fm₁) =
⊥-elim (All¬-¬Any k≢ks (forget k',v'∈fm'₁))
... | (v'' , (v'≈v'' , there k',v'∈fm'₂)) =
(v'' , (v'≈v'' , k',v'∈fm'₂))
narrow : {fm₁ fm₂ : FiniteMap (k ks)}
fm₁ ⊆ᵐ fm₂ pop fm₁ ⊆ᵐ pop fm₂
narrow {fm₁} {fm₂} x = narrow₂ {pop fm₁} (narrow₁ {fm₂ = fm₂} x)
k,v∈pop⇒k,v∈ : {k : A} {ks : List A} {k' : A} {v : B} (fm : FiniteMap (k ks))
(k' , v) ∈ᵐ pop fm (¬ k k' × ((k' , v) ∈ᵐ fm))
k,v∈pop⇒k,v∈ {k} {ks} {k'} {v} (m@((k , _) fm' , push k≢ks uks') , refl) k',v∈fm =
( (λ { refl All¬-¬Any k≢ks (forget k',v∈fm) })
, there k',v∈fm
)
k,v∈⇒k,v∈pop : {k : A} {ks : List A} {k' : A} {v : B} (fm : FiniteMap (k ks))
¬ k k' (k' , v) ∈ᵐ fm (k' , v) ∈ᵐ pop fm
k,v∈⇒k,v∈pop (m@(_ _ , push k≢ks _) , refl) k≢k' (here refl) = ⊥-elim (k≢k' refl)
k,v∈⇒k,v∈pop (m@(_ _ , push k≢ks _) , refl) k≢k' (there k,v'∈fm') = k,v'∈fm'
pop-⊔-distr : {k : A} {ks : List A} (fm₁ fm₂ : FiniteMap (k ks))
_≈_ _ (pop (_⊔_ _ fm₁ fm₂)) ((_⊔_ _ (pop fm₁) (pop fm₂)))
pop-⊔-distr {k} {ks} fm₁@(m₁ , _) fm₂@(m₂ , _) =
(pfm₁fm₂⊆pfm₁pfm₂ , pfm₁pfm₂⊆pfm₁fm₂)
where
-- pfm₁fm₂⊆pfm₁pfm₂ = {!!}
pfm₁fm₂⊆pfm₁pfm₂ : pop (_⊔_ _ fm₁ fm₂) ⊆ᵐ (_⊔_ _ (pop fm₁) (pop fm₂))
pfm₁fm₂⊆pfm₁pfm₂ k' v' k',v'∈pfm₁fm₂
with (k≢k' , k',v'∈fm₁fm₂) k,v∈pop⇒k,v∈ (_⊔_ _ fm₁ fm₂) k',v'∈pfm₁fm₂
with ((v₁ , v₂) , (refl , (k,v₁∈fm₁ , k,v₂∈fm₂)))
Provenance-union fm₁ fm₂ k',v'∈fm₁fm₂
with k',v₁∈pfm₁ k,v∈⇒k,v∈pop fm₁ k≢k' k,v₁∈fm₁
with k',v₂∈pfm₂ k,v∈⇒k,v∈pop fm₂ k≢k' k,v₂∈fm₂
=
( v₁ ⊔₂ v₂
, (IsLattice.≈-refl lB
, ⊔-combines {m₁ = proj₁ (pop fm₁)}
{m₂ = proj₁ (pop fm₂)}
k',v₁∈pfm₁ k',v₂∈pfm₂
)
)
pfm₁pfm₂⊆pfm₁fm₂ : (_⊔_ _ (pop fm₁) (pop fm₂)) ⊆ᵐ pop (_⊔_ _ fm₁ fm₂)
pfm₁pfm₂⊆pfm₁fm₂ k' v' k',v'∈pfm₁pfm₂
with ((v₁ , v₂) , (refl , (k,v₁∈pfm₁ , k,v₂∈pfm₂)))
Provenance-union (pop fm₁) (pop fm₂) k',v'∈pfm₁pfm₂
with (k≢k' , k',v₁∈fm₁) k,v∈pop⇒k,v∈ fm₁ k,v₁∈pfm₁
with (_ , k',v₂∈fm₂) k,v∈pop⇒k,v∈ fm₂ k,v₂∈pfm₂
=
( v₁ ⊔₂ v₂
, ( IsLattice.≈-refl lB
, k,v∈⇒k,v∈pop (_⊔_ _ fm₁ fm₂) k≢k'
(⊔-combines {m₁ = m₁} {m₂ = m₂}
k',v₁∈fm₁ k',v₂∈fm₂)
)
)
from-rest : {k : A} {ks : List A} (fm : FiniteMap (k ks))
proj₂ (from fm) from (pop fm)
from-rest (((_ fm') , push _ ufm') , refl) = refl
from-preserves-≈ : {ks : List A} {fm₁ fm₂ : FiniteMap ks}
_≈_ _ fm₁ fm₂ (_≈ⁱᵖ_ {length ks}) (from fm₁) (from fm₂)
from-preserves-≈ {[]} {_} {_} _ = IsEquivalence.≈-refl ≈ᵘ-equiv
from-preserves-≈ {k ks'} {fm₁@(m₁ , _)} {fm₂@(m₂ , _)} fm₁≈fm₂@(kvs₁⊆kvs₂ , kvs₂⊆kvs₁)
with first-key-in-map fm₁
| first-key-in-map fm₂
| from-first-value fm₁
| from-first-value fm₂
... | (v₁ , k,v₁∈fm₁) | (v₂ , k,v₂∈fm₂) | refl | refl
with kvs₁⊆kvs₂ _ _ k,v₁∈fm₁
... | (v₁' , (v₁≈v₁' , k,v₁'∈fm₂))
rewrite Map-functional {m = m₂} k,v₂∈fm₂ k,v₁'∈fm₂
rewrite from-rest fm₁ rewrite from-rest fm₂
=
( v₁≈v₁'
, from-preserves-≈ {ks'} {pop fm₁} {pop fm₂}
(pop-≈ fm₁ fm₂ fm₁≈fm₂)
)
to-preserves-≈ : {ks : List A} (uks : Unique ks) {ip₁ ip₂ : IterProd (length ks)}
_≈ⁱᵖ_ {length ks} ip₁ ip₂ _≈_ _ (to uks ip₁) (to uks ip₂)
to-preserves-≈ {[]} empty {tt} {tt} _ = ((λ k v ()), (λ k v ()))
to-preserves-≈ {k ks'} uks@(push k≢ks' uks') {ip₁@(v₁ , rest₁)} {ip₂@(v₂ , rest₂)} (v₁≈v₂ , rest₁≈rest₂) = (fm₁⊆fm₂ , fm₂⊆fm₁)
where
inductive-step : {v₁ v₂ : B} {rest₁ rest₂ : IterProd (length ks')}
v₁ ≈₂ v₂ _≈ⁱᵖ_ {length ks'} rest₁ rest₂
to uks (v₁ , rest₁) ⊆ᵐ to uks (v₂ , rest₂)
inductive-step {v₁} {v₂} {rest₁} {rest₂} v₁≈v₂ rest₁≈rest₂ k v k,v∈kvs₁
with ((fm'₁ , ufm'₁) , fm'₁≡ks') to uks' rest₁ in p₁
with ((fm'₂ , ufm'₂) , fm'₂≡ks') to uks' rest₂ in p₂
with k,v∈kvs₁
... | here refl = (v₂ , (v₁≈v₂ , here refl))
... | there k,v∈fm'₁ with refl p₁ with refl p₂ =
let
(fm'₁⊆fm'₂ , _) = to-preserves-≈ uks' {rest₁} {rest₂}
rest₁≈rest₂
(v' , (v≈v' , k,v'∈kvs₁)) = fm'₁⊆fm'₂ k v k,v∈fm'₁
in
(v' , (v≈v' , there k,v'∈kvs₁))
fm₁⊆fm₂ : to uks ip₁ ⊆ᵐ to uks ip₂
fm₁⊆fm₂ = inductive-step v₁≈v₂ rest₁≈rest₂
fm₂⊆fm₁ : to uks ip₂ ⊆ᵐ to uks ip₁
fm₂⊆fm₁ = inductive-step (≈₂-sym v₁≈v₂)
(IP.≈-sym {length ks'} rest₁≈rest₂)
from-⊔-distr : {ks : List A} (fm₁ fm₂ : FiniteMap ks)
_≈ⁱᵖ_ {length ks} (from (_⊔_ _ fm₁ fm₂))
(_⊔ⁱᵖ_ {ks} (from fm₁) (from fm₂))
from-⊔-distr {[]} fm₁ fm₂ = IsEquivalence.≈-refl ≈ᵘ-equiv
from-⊔-distr {k ks} fm₁@(m₁ , _) fm₂@(m₂ , _)
with first-key-in-map (_⊔_ _ fm₁ fm₂)
| first-key-in-map fm₁
| first-key-in-map fm₂
| from-first-value (_⊔_ _ fm₁ fm₂)
| from-first-value fm₁ | from-first-value fm₂
... | (v , k,v∈fm₁fm₂) | (v₁ , k,v₁∈fm₁) | (v₂ , k,v₂∈fm₂) | refl | refl | refl
with Expr-Provenance k ((` m₁) (` m₂)) (forget k,v∈fm₁fm₂)
... | (_ , (in _ k∉km₂ , _)) = ⊥-elim (k∉km₂ (forget k,v₂∈fm₂))
... | (_ , (in k∉km₁ _ , _)) = ⊥-elim (k∉km₁ (forget k,v₁∈fm₁))
... | (v₁⊔v₂ , (bothᵘ {v₁'} {v₂'} (single k,v₁'∈m₁) (single k,v₂'∈m₂) , k,v₁⊔v₂∈m₁m₂))
rewrite Map-functional {m = m₁} k,v₁∈fm₁ k,v₁'∈m₁
rewrite Map-functional {m = m₂} k,v₂∈fm₂ k,v₂'∈m₂
rewrite Map-functional {m = proj₁ (_⊔_ _ fm₁ fm₂)} k,v∈fm₁fm₂ k,v₁⊔v₂∈m₁m₂
rewrite from-rest (_⊔_ _ fm₁ fm₂) rewrite from-rest fm₁ rewrite from-rest fm₂
= ( IsLattice.≈-refl lB
, IsEquivalence.≈-trans
(IP.≈-equiv {length ks})
(from-preserves-≈ {_} {pop (_⊔_ _ fm₁ fm₂)}
{_⊔_ _ (pop fm₁) (pop fm₂)}
(pop-⊔-distr fm₁ fm₂))
((from-⊔-distr (pop fm₁) (pop fm₂)))
)
to-⊔-distr : {ks : List A} (uks : Unique ks) (ip₁ ip₂ : IterProd (length ks))
_≈_ _ (to uks (_⊔ⁱᵖ_ {ks} ip₁ ip₂)) ((_⊔_ _ (to uks ip₁) (to uks ip₂)))
to-⊔-distr {[]} empty tt tt = ((λ k v ()), (λ k v ()))
to-⊔-distr {ks@(k ks')} uks@(push k≢ks' uks') ip₁@(v₁ , rest₁) ip₂@(v₂ , rest₂) = (fm⊆fm₁fm₂ , fm₁fm₂⊆fm)
where
fm₁ = to uks ip₁
fm₁' = to uks' rest₁
fm₂ = to uks ip₂
fm₂' = to uks' rest₂
fm = to uks (_⊔ⁱᵖ_ {k ks'} ip₁ ip₂)
fm⊆fm₁fm₂ : fm ⊆ᵐ (_⊔_ _ fm₁ fm₂)
fm⊆fm₁fm₂ k v (here refl) =
(v₁ ⊔₂ v₂
, (IsLattice.≈-refl lB
, ⊔-combines {k} {v₁} {v₂} {proj₁ fm₁} {proj₁ fm₂}
(here refl) (here refl)
)
)
fm⊆fm₁fm₂ k' v (there k',v∈fm')
with (fm'⊆fm'₁fm'₂ , _) to-⊔-distr uks' rest₁ rest₂
with (v' , (v₁⊔v₂≈v' , k',v'∈fm'₁fm'₂))
fm'⊆fm'₁fm'₂ k' v k',v∈fm'
with (_ , (refl , (v₁∈fm'₁ , v₂∈fm'₂)))
Provenance-union fm₁' fm₂' k',v'∈fm'₁fm'₂ =
( v'
, ( v₁⊔v₂≈v'
, ⊔-combines {m₁ = proj₁ fm₁} {m₂ = proj₁ fm₂}
(there v₁∈fm'₁) (there v₂∈fm'₂)
)
)
fm₁fm₂⊆fm : (_⊔_ _ fm₁ fm₂) ⊆ᵐ fm
fm₁fm₂⊆fm k' v k',v∈fm₁fm₂
with (_ , fm'₁fm'₂⊆fm')
to-⊔-distr uks' rest₁ rest₂
with (_ , (refl , (v₁∈fm₁ , v₂∈fm₂)))
Provenance-union fm₁ fm₂ k',v∈fm₁fm₂
with v₁∈fm₁ | v₂∈fm₂
... | here refl | here refl =
(v , (IsLattice.≈-refl lB , here refl))
... | here refl | there k',v₂∈fm₂' =
⊥-elim (All¬-¬Any k≢ks' (subst (k' ∈ˡ_) (proj₂ fm₂')
(forget k',v₂∈fm₂')))
... | there k',v₁∈fm₁' | here refl =
⊥-elim (All¬-¬Any k≢ks' (subst (k' ∈ˡ_) (proj₂ fm₁')
(forget k',v₁∈fm₁')))
... | there k',v₁∈fm₁' | there k',v₂∈fm₂' =
let
k',v₁v₂∈fm₁'fm₂' =
⊔-combines {m₁ = proj₁ fm₁'} {m₂ = proj₁ fm₂'}
k',v₁∈fm₁' k',v₂∈fm₂'
(v' , (v₁⊔v₂≈v' , v'∈fm')) =
fm'₁fm'₂⊆fm' _ _ k',v₁v₂∈fm₁'fm₂'
in
(v' , (v₁⊔v₂≈v' , there v'∈fm'))
module FixedHeight {ks : List A} {{≈₂-Decidable : IsDecidable _≈₂_}} {h₂ : } {{fhB : FixedHeight₂ h₂}} (uks : Unique ks) where
import Isomorphism
open Isomorphism.TransportFiniteHeight
(IP.isFiniteHeightLattice {k = length ks} {{fhB = fixedHeightᵘ}}) (isLattice ks)
{f = to uks} {g = from {ks}}
(to-preserves-≈ uks) (from-preserves-≈ {ks})
(to-⊔-distr uks) (from-⊔-distr {ks})
(from-to-inverseʳ uks) (from-to-inverseˡ uks)
using (isFiniteHeightLattice; finiteHeightLattice; fixedHeight) public
-- Helpful lemma: all entries of the 'bottom' map are assigned to bottom.
open Height (IsFiniteHeightLattice.fixedHeight isFiniteHeightLattice) using ()
⊥-contains-bottoms : {k : A} {v : B} (k , v) ∈ᵐ v (Height.⊥ fhB)
⊥-contains-bottoms {k} {v} k,v∈⊥
rewrite IP.⊥-built {length ks} {{fhB = fixedHeightᵘ}} =
to-build uks k v k,v∈⊥
open WithKeys ks public
module FixedHeight = IterProdIsomorphism.FixedHeight

427
Lattice/FiniteValueMap.agda
View File

@@ -1,427 +0,0 @@
-- Because iterated products currently require both A and B to be of the same
-- universe, and the FiniteMap is written in a universe-polymorphic way,
-- specialize the FiniteMap module with Set-typed types only.
open import Lattice
open import Equivalence
open import Relation.Binary.PropositionalEquality as Eq
using (_≡_; refl; sym; trans; cong; subst)
open import Relation.Binary.Definitions using (Decidable)
open import Agda.Primitive using (Level) renaming (_⊔_ to _⊔_)
open import Function.Definitions using (Inverseˡ; Inverseʳ)
module Lattice.FiniteValueMap {A : Set} {B : Set}
{_≈₂_ : B B Set}
{_⊔₂_ : B B B} {_⊓₂_ : B B B}
(≡-dec-A : Decidable (_≡_ {_} {A}))
(lB : IsLattice B _≈₂_ _⊔₂_ _⊓₂_) where
open import Data.List using (List; length; []; _∷_; map)
open import Data.List.Membership.Propositional using () renaming (_∈_ to _∈ˡ_)
open import Data.Nat using ()
open import Data.Product using (Σ; proj₁; proj₂; _×_)
open import Data.Empty using (⊥-elim)
open import Utils using (Unique; push; empty; All¬-¬Any)
open import Data.Product using (_,_)
open import Data.List.Properties using (∷-injectiveʳ)
open import Data.List.Relation.Unary.All using (All)
open import Data.List.Relation.Unary.Any using (Any; here; there)
open import Relation.Nullary using (¬_)
open import Isomorphism using (IsInverseˡ; IsInverseʳ)
open import Chain using (Height)
open import Lattice.Map ≡-dec-A lB
using
( subset-impl
; locate
; Map-functional
; Expr-Provenance
; Expr-Provenance-≡
; _∩_; __; `_
; in₁; in₂; bothᵘ; single
; ⊔-combines
)
open import Lattice.FiniteMap ≡-dec-A lB public
module IterProdIsomorphism where
open import Data.Unit using (; tt)
open import Lattice.Unit using ()
renaming
( _≈_ to _≈ᵘ_
; _⊔_ to _⊔ᵘ_
; _⊓_ to _⊓ᵘ_
; ≈-dec to ≈ᵘ-dec
; isLattice to isLatticeᵘ
; ≈-equiv to ≈ᵘ-equiv
; fixedHeight to fixedHeightᵘ
)
open import Lattice.IterProd _≈₂_ _≈ᵘ_ _⊔₂_ _⊔ᵘ_ _⊓₂_ _⊓ᵘ_ lB isLatticeᵘ
as IP
using (IterProd)
open IsLattice lB using ()
renaming
( ≈-trans to ≈₂-trans
; ≈-sym to ≈₂-sym
; FixedHeight to FixedHeight₂
)
from : {ks : List A} FiniteMap ks IterProd (length ks)
from {[]} (([] , _) , _) = tt
from {k ks'} (((k' , v) fm' , push _ uks') , refl) =
(v , from ((fm' , uks'), refl))
to : {ks : List A} Unique ks IterProd (length ks) FiniteMap ks
to {[]} _ = (([] , empty) , refl)
to {k ks'} (push k≢ks' uks') (v , rest) =
let
((fm' , ufm') , fm'≡ks') = to uks' rest
-- This would be easier if we pattern matched on the equiality proof
-- to get refl, but that makes it harder to reason about 'to' when
-- the arguments are not known to be refl.
k≢fm' = subst (λ ks All (λ k' ¬ k k') ks) (sym fm'≡ks') k≢ks'
kvs≡ks = cong (k ∷_) fm'≡ks'
in
(((k , v) fm' , push k≢fm' ufm') , kvs≡ks)
private
_≈ᵐ_ : {ks : List A} FiniteMap ks FiniteMap ks Set
_≈ᵐ_ {ks} = _≈_ ks
_⊔ᵐ_ : {ks : List A} FiniteMap ks FiniteMap ks FiniteMap ks
_⊔ᵐ_ {ks} = _⊔_ ks
_⊆ᵐ_ : {ks₁ ks₂ : List A} FiniteMap ks₁ FiniteMap ks₂ Set
_⊆ᵐ_ fm₁ fm₂ = subset-impl (proj₁ (proj₁ fm₁)) (proj₁ (proj₁ fm₂))
_≈ⁱᵖ_ : {n : } IterProd n IterProd n Set
_≈ⁱᵖ_ {n} = IP._≈_ n
_⊔ⁱᵖ_ : {ks : List A}
IterProd (length ks) IterProd (length ks) IterProd (length ks)
_⊔ⁱᵖ_ {ks} = IP._⊔_ (length ks)
_∈ᵐ_ : {ks : List A} A × B FiniteMap ks Set
_∈ᵐ_ {ks} = _∈_ ks
to-build : {b : B} {ks : List A} (uks : Unique ks)
let fm = to uks (IP.build b tt (length ks))
in (k : A) (v : B) (k , v) ∈ᵐ fm v b
to-build {b} {k ks'} (push _ uks') k v (here refl) = refl
to-build {b} {k ks'} (push _ uks') k' v (there k',v∈m') =
to-build {ks = ks'} uks' k' v k',v∈m'
-- The left inverse is: from (to x) = x
from-to-inverseˡ : {ks : List A} (uks : Unique ks)
IsInverseˡ (_≈ᵐ_ {ks}) (_≈ⁱᵖ_ {length ks})
(from {ks}) (to {ks} uks)
from-to-inverseˡ {[]} _ _ = IsEquivalence.≈-refl (IP.≈-equiv 0)
from-to-inverseˡ {k ks'} (push k≢ks' uks') (v , rest)
with ((fm' , ufm') , refl) to uks' rest in p rewrite sym p =
(IsLattice.≈-refl lB , from-to-inverseˡ {ks'} uks' rest)
-- the rewrite here is needed because the IH is in terms of `to uks' rest`,
-- but we end up with the 'unpacked' form (fm', ...). So, put it back
-- in the 'packed' form after we've performed enough inspection
-- to know we take the cons branch of `to`.
-- The map has its own uniqueness proof, but the call to 'to' needs a standalone
-- uniqueness proof too. Work with both proofs as needed to thread things through.
--
-- The right inverse is: to (from x) = x
from-to-inverseʳ : {ks : List A} (uks : Unique ks)
IsInverseʳ (_≈ᵐ_ {ks}) (_≈ⁱᵖ_ {length ks})
(from {ks}) (to {ks} uks)
from-to-inverseʳ {[]} _ (([] , empty) , kvs≡ks) rewrite kvs≡ks =
( (λ k v ())
, (λ k v ())
)
from-to-inverseʳ {k ks'} uks@(push _ uks'₁) fm₁@(((k , v) fm'₁ , push _ uks'₂) , refl)
with to uks'₁ (from ((fm'₁ , uks'₂) , refl))
| from-to-inverseʳ {ks'} uks'₁ ((fm'₁ , uks'₂) , refl)
... | ((fm'₂ , ufm'₂) , _)
| (fm'₂⊆fm'₁ , fm'₁⊆fm'₂) = (m₂⊆m₁ , m₁⊆m₂)
where
kvs₁ = (k , v) fm'₁
kvs₂ = (k , v) fm'₂
m₁⊆m₂ : subset-impl kvs₁ kvs₂
m₁⊆m₂ k' v' (here refl) =
(v' , (IsLattice.≈-refl lB , here refl))
m₁⊆m₂ k' v' (there k',v'∈fm'₁) =
let (v'' , (v'≈v'' , k',v''∈fm'₂)) =
fm'₁⊆fm'₂ k' v' k',v'∈fm'₁
in (v'' , (v'≈v'' , there k',v''∈fm'₂))
m₂⊆m₁ : subset-impl kvs₂ kvs₁
m₂⊆m₁ k' v' (here refl) =
(v' , (IsLattice.≈-refl lB , here refl))
m₂⊆m₁ k' v' (there k',v'∈fm'₂) =
let (v'' , (v'≈v'' , k',v''∈fm'₁)) =
fm'₂⊆fm'₁ k' v' k',v'∈fm'₂
in (v'' , (v'≈v'' , there k',v''∈fm'₁))
FromBothMaps : (k : A) (v : B) {ks : List A} (fm₁ fm₂ : FiniteMap ks) Set
FromBothMaps k v fm₁ fm₂ =
Σ (B × B)
(λ (v₁ , v₂) ( (v v₁ ⊔₂ v₂) × ((k , v₁) ∈ᵐ fm₁ × (k , v₂) ∈ᵐ fm₂)))
Provenance-union : {ks : List A} (fm₁ fm₂ : FiniteMap ks) {k : A} {v : B}
(k , v) ∈ᵐ (fm₁ ⊔ᵐ fm₂) FromBothMaps k v fm₁ fm₂
Provenance-union fm₁@(m₁ , ks₁≡ks) fm₂@(m₂ , ks₂≡ks) {k} {v} k,v∈fm₁fm₂
with Expr-Provenance-≡ ((` m₁) (` m₂)) k,v∈fm₁fm₂
... | in (single k,v∈m₁) k∉km₂
with k∈km₁ (forget k,v∈m₁)
rewrite trans ks₁≡ks (sym ks₂≡ks) =
⊥-elim (k∉km₂ k∈km₁)
... | in k∉km₁ (single k,v∈m₂)
with k∈km₂ (forget k,v∈m₂)
rewrite trans ks₁≡ks (sym ks₂≡ks) =
⊥-elim (k∉km₁ k∈km₂)
... | bothᵘ {v₁} {v₂} (single k,v₁∈m₁) (single k,v₂∈m₂) =
((v₁ , v₂) , (refl , (k,v₁∈m₁ , k,v₂∈m₂)))
private
first-key-in-map : {k : A} {ks : List A} (fm : FiniteMap (k ks))
Σ B (λ v (k , v) ∈ᵐ fm)
first-key-in-map (((k , v) _ , _) , refl) = (v , here refl)
from-first-value : {k : A} {ks : List A} (fm : FiniteMap (k ks))
proj₁ (from fm) proj₁ (first-key-in-map fm)
from-first-value {k} {ks} (((k , v) _ , push _ _) , refl) = refl
-- We need pop because reasoning about two distinct 'refl' pattern
-- matches is giving us unification errors. So, stash the 'refl' pattern
-- matching into a helper functions, and write solutions in terms
-- of that.
pop : {k : A} {ks : List A} FiniteMap (k ks) FiniteMap ks
pop (((_ fm') , push _ ufm') , refl) = ((fm' , ufm') , refl)
pop-≈ : {k : A} {ks : List A} (fm₁ fm₂ : FiniteMap (k ks))
fm₁ ≈ᵐ fm₂ pop fm₁ ≈ᵐ pop fm₂
pop-≈ {k} {ks} fm₁ fm₂ (fm₁⊆fm₂ , fm₂⊆fm₁) =
(narrow fm₁⊆fm₂ , narrow fm₂⊆fm₁)
where
narrow₁ : {fm₁ fm₂ : FiniteMap (k ks)}
fm₁ ⊆ᵐ fm₂ pop fm₁ ⊆ᵐ fm₂
narrow₁ {(_ _ , push _ _) , refl} kvs₁⊆kvs₂ k' v' k',v'∈fm'₁ =
kvs₁⊆kvs₂ k' v' (there k',v'∈fm'₁)
narrow₂ : {fm₁ : FiniteMap ks} {fm₂ : FiniteMap (k ks)}
fm₁ ⊆ᵐ fm₂ fm₁ ⊆ᵐ pop fm₂
narrow₂ {fm₁} {fm₂ = (_ fm'₂ , push k≢ks _) , kvs≡ks@refl} kvs₁⊆kvs₂ k' v' k',v'∈fm'₁
with kvs₁⊆kvs₂ k' v' k',v'∈fm'₁
... | (v'' , (v'≈v'' , here refl)) rewrite sym (proj₂ fm₁) =
⊥-elim (All¬-¬Any k≢ks (forget k',v'∈fm'₁))
... | (v'' , (v'≈v'' , there k',v'∈fm'₂)) =
(v'' , (v'≈v'' , k',v'∈fm'₂))
narrow : {fm₁ fm₂ : FiniteMap (k ks)}
fm₁ ⊆ᵐ fm₂ pop fm₁ ⊆ᵐ pop fm₂
narrow {fm₁} {fm₂} x = narrow₂ {pop fm₁} (narrow₁ {fm₂ = fm₂} x)
k,v∈pop⇒k,v∈ : {k : A} {ks : List A} {k' : A} {v : B} (fm : FiniteMap (k ks))
(k' , v) ∈ᵐ pop fm (¬ k k' × ((k' , v) ∈ᵐ fm))
k,v∈pop⇒k,v∈ {k} {ks} {k'} {v} (m@((k , _) fm' , push k≢ks uks') , refl) k',v∈fm =
( (λ { refl All¬-¬Any k≢ks (forget k',v∈fm) })
, there k',v∈fm
)
k,v∈⇒k,v∈pop : {k : A} {ks : List A} {k' : A} {v : B} (fm : FiniteMap (k ks))
¬ k k' (k' , v) ∈ᵐ fm (k' , v) ∈ᵐ pop fm
k,v∈⇒k,v∈pop (m@(_ _ , push k≢ks _) , refl) k≢k' (here refl) = ⊥-elim (k≢k' refl)
k,v∈⇒k,v∈pop (m@(_ _ , push k≢ks _) , refl) k≢k' (there k,v'∈fm') = k,v'∈fm'
pop-⊔-distr : {k : A} {ks : List A} (fm₁ fm₂ : FiniteMap (k ks))
pop (fm₁ ⊔ᵐ fm₂) ≈ᵐ (pop fm₁ ⊔ᵐ pop fm₂)
pop-⊔-distr {k} {ks} fm₁@(m₁ , _) fm₂@(m₂ , _) =
(pfm₁fm₂⊆pfm₁pfm₂ , pfm₁pfm₂⊆pfm₁fm₂)
where
-- pfm₁fm₂⊆pfm₁pfm₂ = {!!}
pfm₁fm₂⊆pfm₁pfm₂ : pop (fm₁ ⊔ᵐ fm₂) ⊆ᵐ (pop fm₁ ⊔ᵐ pop fm₂)
pfm₁fm₂⊆pfm₁pfm₂ k' v' k',v'∈pfm₁fm₂
with (k≢k' , k',v'∈fm₁fm₂) k,v∈pop⇒k,v∈ (fm₁ ⊔ᵐ fm₂) k',v'∈pfm₁fm₂
with ((v₁ , v₂) , (refl , (k,v₁∈fm₁ , k,v₂∈fm₂)))
Provenance-union fm₁ fm₂ k',v'∈fm₁fm₂
with k',v₁∈pfm₁ k,v∈⇒k,v∈pop fm₁ k≢k' k,v₁∈fm₁
with k',v₂∈pfm₂ k,v∈⇒k,v∈pop fm₂ k≢k' k,v₂∈fm₂
=
( v₁ ⊔₂ v₂
, (IsLattice.≈-refl lB
, ⊔-combines {m₁ = proj₁ (pop fm₁)}
{m₂ = proj₁ (pop fm₂)}
k',v₁∈pfm₁ k',v₂∈pfm₂
)
)
pfm₁pfm₂⊆pfm₁fm₂ : (pop fm₁ ⊔ᵐ pop fm₂) ⊆ᵐ pop (fm₁ ⊔ᵐ fm₂)
pfm₁pfm₂⊆pfm₁fm₂ k' v' k',v'∈pfm₁pfm₂
with ((v₁ , v₂) , (refl , (k,v₁∈pfm₁ , k,v₂∈pfm₂)))
Provenance-union (pop fm₁) (pop fm₂) k',v'∈pfm₁pfm₂
with (k≢k' , k',v₁∈fm₁) k,v∈pop⇒k,v∈ fm₁ k,v₁∈pfm₁
with (_ , k',v₂∈fm₂) k,v∈pop⇒k,v∈ fm₂ k,v₂∈pfm₂
=
( v₁ ⊔₂ v₂
, ( IsLattice.≈-refl lB
, k,v∈⇒k,v∈pop (fm₁ ⊔ᵐ fm₂) k≢k'
(⊔-combines {m₁ = m₁} {m₂ = m₂}
k',v₁∈fm₁ k',v₂∈fm₂)
)
)
from-rest : {k : A} {ks : List A} (fm : FiniteMap (k ks))
proj₂ (from fm) from (pop fm)
from-rest (((_ fm') , push _ ufm') , refl) = refl
from-preserves-≈ : {ks : List A} {fm₁ fm₂ : FiniteMap ks}
fm₁ ≈ᵐ fm₂ (_≈ⁱᵖ_ {length ks}) (from fm₁) (from fm₂)
from-preserves-≈ {[]} {_} {_} _ = IsEquivalence.≈-refl ≈ᵘ-equiv
from-preserves-≈ {k ks'} {fm₁@(m₁ , _)} {fm₂@(m₂ , _)} fm₁≈fm₂@(kvs₁⊆kvs₂ , kvs₂⊆kvs₁)
with first-key-in-map fm₁
| first-key-in-map fm₂
| from-first-value fm₁
| from-first-value fm₂
... | (v₁ , k,v₁∈fm₁) | (v₂ , k,v₂∈fm₂) | refl | refl
with kvs₁⊆kvs₂ _ _ k,v₁∈fm₁
... | (v₁' , (v₁≈v₁' , k,v₁'∈fm₂))
rewrite Map-functional {m = m₂} k,v₂∈fm₂ k,v₁'∈fm₂
rewrite from-rest fm₁ rewrite from-rest fm₂
=
( v₁≈v₁'
, from-preserves-≈ {ks'} {pop fm₁} {pop fm₂}
(pop-≈ fm₁ fm₂ fm₁≈fm₂)
)
to-preserves-≈ : {ks : List A} (uks : Unique ks) {ip₁ ip₂ : IterProd (length ks)}
_≈ⁱᵖ_ {length ks} ip₁ ip₂ to uks ip₁ ≈ᵐ to uks ip₂
to-preserves-≈ {[]} empty {tt} {tt} _ = ((λ k v ()), (λ k v ()))
to-preserves-≈ {k ks'} uks@(push k≢ks' uks') {ip₁@(v₁ , rest₁)} {ip₂@(v₂ , rest₂)} (v₁≈v₂ , rest₁≈rest₂) = (fm₁⊆fm₂ , fm₂⊆fm₁)
where
inductive-step : {v₁ v₂ : B} {rest₁ rest₂ : IterProd (length ks')}
v₁ ≈₂ v₂ _≈ⁱᵖ_ {length ks'} rest₁ rest₂
to uks (v₁ , rest₁) ⊆ᵐ to uks (v₂ , rest₂)
inductive-step {v₁} {v₂} {rest₁} {rest₂} v₁≈v₂ rest₁≈rest₂ k v k,v∈kvs₁
with ((fm'₁ , ufm'₁) , fm'₁≡ks') to uks' rest₁ in p₁
with ((fm'₂ , ufm'₂) , fm'₂≡ks') to uks' rest₂ in p₂
with k,v∈kvs₁
... | here refl = (v₂ , (v₁≈v₂ , here refl))
... | there k,v∈fm'₁ with refl p₁ with refl p₂ =
let
(fm'₁⊆fm'₂ , _) = to-preserves-≈ uks' {rest₁} {rest₂}
rest₁≈rest₂
(v' , (v≈v' , k,v'∈kvs₁)) = fm'₁⊆fm'₂ k v k,v∈fm'₁
in
(v' , (v≈v' , there k,v'∈kvs₁))
fm₁⊆fm₂ : to uks ip₁ ⊆ᵐ to uks ip₂
fm₁⊆fm₂ = inductive-step v₁≈v₂ rest₁≈rest₂
fm₂⊆fm₁ : to uks ip₂ ⊆ᵐ to uks ip₁
fm₂⊆fm₁ = inductive-step (≈₂-sym v₁≈v₂)
(IP.≈-sym (length ks') rest₁≈rest₂)
from-⊔-distr : {ks : List A} (fm₁ fm₂ : FiniteMap ks)
_≈ⁱᵖ_ {length ks} (from (fm₁ ⊔ᵐ fm₂))
(_⊔ⁱᵖ_ {ks} (from fm₁) (from fm₂))
from-⊔-distr {[]} fm₁ fm₂ = IsEquivalence.≈-refl ≈ᵘ-equiv
from-⊔-distr {k ks} fm₁@(m₁ , _) fm₂@(m₂ , _)
with first-key-in-map (fm₁ ⊔ᵐ fm₂)
| first-key-in-map fm₁
| first-key-in-map fm₂
| from-first-value (fm₁ ⊔ᵐ fm₂)
| from-first-value fm₁ | from-first-value fm₂
... | (v , k,v∈fm₁fm₂) | (v₁ , k,v₁∈fm₁) | (v₂ , k,v₂∈fm₂) | refl | refl | refl
with Expr-Provenance k ((` m₁) (` m₂)) (forget k,v∈fm₁fm₂)
... | (_ , (in _ k∉km₂ , _)) = ⊥-elim (k∉km₂ (forget k,v₂∈fm₂))
... | (_ , (in k∉km₁ _ , _)) = ⊥-elim (k∉km₁ (forget k,v₁∈fm₁))
... | (v₁⊔v₂ , (bothᵘ {v₁'} {v₂'} (single k,v₁'∈m₁) (single k,v₂'∈m₂) , k,v₁⊔v₂∈m₁m₂))
rewrite Map-functional {m = m₁} k,v₁∈fm₁ k,v₁'∈m₁
rewrite Map-functional {m = m₂} k,v₂∈fm₂ k,v₂'∈m₂
rewrite Map-functional {m = proj₁ (fm₁ ⊔ᵐ fm₂)} k,v∈fm₁fm₂ k,v₁⊔v₂∈m₁m₂
rewrite from-rest (fm₁ ⊔ᵐ fm₂) rewrite from-rest fm₁ rewrite from-rest fm₂
= ( IsLattice.≈-refl lB
, IsEquivalence.≈-trans
(IP.≈-equiv (length ks))
(from-preserves-≈ {_} {pop (fm₁ ⊔ᵐ fm₂)}
{pop fm₁ ⊔ᵐ pop fm₂}
(pop-⊔-distr fm₁ fm₂))
((from-⊔-distr (pop fm₁) (pop fm₂)))
)
to-⊔-distr : {ks : List A} (uks : Unique ks) (ip₁ ip₂ : IterProd (length ks))
to uks (_⊔ⁱᵖ_ {ks} ip₁ ip₂) ≈ᵐ (to uks ip₁ ⊔ᵐ to uks ip₂)
to-⊔-distr {[]} empty tt tt = ((λ k v ()), (λ k v ()))
to-⊔-distr {ks@(k ks')} uks@(push k≢ks' uks') ip₁@(v₁ , rest₁) ip₂@(v₂ , rest₂) = (fm⊆fm₁fm₂ , fm₁fm₂⊆fm)
where
fm₁ = to uks ip₁
fm₁' = to uks' rest₁
fm₂ = to uks ip₂
fm₂' = to uks' rest₂
fm = to uks (_⊔ⁱᵖ_ {k ks'} ip₁ ip₂)
fm⊆fm₁fm₂ : fm ⊆ᵐ (fm₁ ⊔ᵐ fm₂)
fm⊆fm₁fm₂ k v (here refl) =
(v₁ ⊔₂ v₂
, (IsLattice.≈-refl lB
, ⊔-combines {k} {v₁} {v₂} {proj₁ fm₁} {proj₁ fm₂}
(here refl) (here refl)
)
)
fm⊆fm₁fm₂ k' v (there k',v∈fm')
with (fm'⊆fm'₁fm'₂ , _) to-⊔-distr uks' rest₁ rest₂
with (v' , (v₁⊔v₂≈v' , k',v'∈fm'₁fm'₂))
fm'⊆fm'₁fm'₂ k' v k',v∈fm'
with (_ , (refl , (v₁∈fm'₁ , v₂∈fm'₂)))
Provenance-union fm₁' fm₂' k',v'∈fm'₁fm'₂ =
( v'
, ( v₁⊔v₂≈v'
, ⊔-combines {m₁ = proj₁ fm₁} {m₂ = proj₁ fm₂}
(there v₁∈fm'₁) (there v₂∈fm'₂)
)
)
fm₁fm₂⊆fm : (fm₁ ⊔ᵐ fm₂) ⊆ᵐ fm
fm₁fm₂⊆fm k' v k',v∈fm₁fm₂
with (_ , fm'₁fm'₂⊆fm')
to-⊔-distr uks' rest₁ rest₂
with (_ , (refl , (v₁∈fm₁ , v₂∈fm₂)))
Provenance-union fm₁ fm₂ k',v∈fm₁fm₂
with v₁∈fm₁ | v₂∈fm₂
... | here refl | here refl =
(v , (IsLattice.≈-refl lB , here refl))
... | here refl | there k',v₂∈fm₂' =
⊥-elim (All¬-¬Any k≢ks' (subst (k' ∈ˡ_) (proj₂ fm₂')
(forget k',v₂∈fm₂')))
... | there k',v₁∈fm₁' | here refl =
⊥-elim (All¬-¬Any k≢ks' (subst (k' ∈ˡ_) (proj₂ fm₁')
(forget k',v₁∈fm₁')))
... | there k',v₁∈fm₁' | there k',v₂∈fm₂' =
let
k',v₁v₂∈fm₁'fm₂' =
⊔-combines {m₁ = proj₁ fm₁'} {m₂ = proj₁ fm₂'}
k',v₁∈fm₁' k',v₂∈fm₂'
(v' , (v₁⊔v₂≈v' , v'∈fm')) =
fm'₁fm'₂⊆fm' _ _ k',v₁v₂∈fm₁'fm₂'
in
(v' , (v₁⊔v₂≈v' , there v'∈fm'))
module WithUniqueKeysAndFixedHeight {ks : List A} (uks : Unique ks) (≈₂-dec : Decidable _≈₂_) (h₂ : ) (fhB : FixedHeight₂ h₂) where
import Isomorphism
open Isomorphism.TransportFiniteHeight
(IP.isFiniteHeightLattice (length ks) ≈₂-dec ≈ᵘ-dec h₂ 0 fhB fixedHeightᵘ) (isLattice ks)
{f = to uks} {g = from {ks}}
(to-preserves-≈ uks) (from-preserves-≈ {ks})
(to-⊔-distr uks) (from-⊔-distr {ks})
(from-to-inverseʳ uks) (from-to-inverseˡ uks)
using (isFiniteHeightLattice; finiteHeightLattice) public
-- Helpful lemma: all entries of the 'bottom' map are assigned to bottom.
open Height (IsFiniteHeightLattice.fixedHeight isFiniteHeightLattice) using ()
⊥-contains-bottoms : {k : A} {v : B} (k , v) ∈ᵐ v (Height.⊥ fhB)
⊥-contains-bottoms {k} {v} k,v∈⊥
rewrite IP.⊥-built (length ks) ≈₂-dec ≈ᵘ-dec h₂ 0 fhB fixedHeightᵘ =
to-build uks k v k,v∈⊥

121
Lattice/IterProd.agda
View File

@@ -1,14 +1,15 @@
open import Lattice
open import Data.Unit using ()
-- Due to universe levels, it becomes relatively annoying to handle the case
-- where the levels of A and B are not the same. For the time being, constrain
-- them to be the same.
module Lattice.IterProd {a} {A B : Set a}
(_≈₁_ : A A Set a) (_≈₂_ : B B Set a)
(_⊔₁_ : A A A) (_⊔₂_ : B B B)
(_⊓₁_ : A A A) (_⊓₂_ : B B B)
(lA : IsLattice A _≈₁_ _⊔₁_ _⊓₁_) (lB : IsLattice B _≈₂_ _⊔₂_ _⊓₂_) where
module Lattice.IterProd {a} (A B : Set a)
{_≈₁_ : A A Set a} {_≈₂_ : B B Set a}
{_⊔₁_ : A A A} {_⊔₂_ : B B B}
{_⊓₁_ : A A A} {_⊓₂_ : B B B}
{{lA : IsLattice A _≈₁_ _⊔₁_ _⊓₁_}} {{lB : IsLattice B _≈₂_ _⊔₂_ _⊓₂_}} (dummy : ) where
open import Agda.Primitive using (lsuc)
open import Data.Nat using (; zero; suc; _+_)
@@ -39,11 +40,11 @@ build a b (suc s) = (a , build a b s)
private
record RequiredForFixedHeight : Set (lsuc a) where
field
≈₁-dec : IsDecidable _≈₁_
≈₂-dec : IsDecidable _≈₂_
{{≈₁-Decidable}} : IsDecidable _≈₁_
{{≈₂-Decidable}} : IsDecidable _≈₂_
h₁ h₂ :
fhA : FixedHeight₁ h₁
fhB : FixedHeight₂ h₂
{{fhA}} : FixedHeight₁ h₁
{{fhB}} : FixedHeight₂ h₂
⊥₁ : A
⊥₁ = Height.⊥ fhA
@@ -58,7 +59,7 @@ private
field
height :
fixedHeight : IsLattice.FixedHeight isLattice height
≈-dec : IsDecidable _≈_
≈-Decidable : IsDecidable _≈_
⊥-correct : Height.⊥ fixedHeight
@@ -84,7 +85,7 @@ private
; isFiniteHeightIfSupported = λ req record
{ height = RequiredForFixedHeight.h₂ req
; fixedHeight = RequiredForFixedHeight.fhB req
; ≈-dec = RequiredForFixedHeight.≈₂-dec req
; ≈-Decidable = RequiredForFixedHeight.≈₂-Decidable req
; ⊥-correct = refl
}
}
@@ -101,10 +102,9 @@ private
{ height = (RequiredForFixedHeight.h₁ req) + IsFiniteHeightWithBotAndDecEq.height fhlRest
; fixedHeight =
P.fixedHeight
(RequiredForFixedHeight.≈₁-dec req) (IsFiniteHeightWithBotAndDecEq.≈-dec fhlRest)
(RequiredForFixedHeight.h₁ req) (IsFiniteHeightWithBotAndDecEq.height fhlRest)
(RequiredForFixedHeight.fhA req) (IsFiniteHeightWithBotAndDecEq.fixedHeight fhlRest)
; ≈-dec = P.≈-dec (RequiredForFixedHeight.≈₁-dec req) (IsFiniteHeightWithBotAndDecEq.≈-dec fhlRest)
{{≈₂-Decidable = IsFiniteHeightWithBotAndDecEq.≈-Decidable fhlRest}}
{{fhB = IsFiniteHeightWithBotAndDecEq.fixedHeight fhlRest}}
; ≈-Decidable = P.≈-Decidable {{≈₂-Decidable = IsFiniteHeightWithBotAndDecEq.≈-Decidable fhlRest}}
; ⊥-correct =
cong ((Height.⊥ (RequiredForFixedHeight.fhA req)) ,_)
(IsFiniteHeightWithBotAndDecEq.⊥-correct fhlRest)
@@ -112,56 +112,57 @@ private
}
where
everythingRest = everything k'
import Lattice.Prod A (IterProd k') {{lB = Everything.isLattice everythingRest}} as P
import Lattice.Prod
_≈₁_ (Everything._≈_ everythingRest)
_⊔₁_ (Everything._⊔_ everythingRest)
_⊓₁_ (Everything._⊓_ everythingRest)
lA (Everything.isLattice everythingRest) as P
module _ {k : } where
open Everything (everything k) using (_≈_; _⊔_; _⊓_) public
open Lattice.IsLattice (Everything.isLattice (everything k)) public
module _ (k : ) where
open Everything (everything k) using (_≈_; _⊔_; _⊓_; isLattice) public
open Lattice.IsLattice isLattice public
instance
isLattice = Everything.isLattice (everything k)
lattice : Lattice (IterProd k)
lattice = record
{ _≈_ = _≈_
; _⊔_ = _⊔_
; _⊓_ = _⊓_
; isLattice = isLattice
}
module _ (≈₁-dec : IsDecidable _≈₁_) (≈₂-dec : IsDecidable _≈₂_)
(h₁ h₂ : )
(fhA : FixedHeight₁ h₁) (fhB : FixedHeight₂ h₂) where
private
required : RequiredForFixedHeight
required = record
{ ≈₁-dec = ≈₁-dec
; ≈₂-dec = ≈₂-dec
; h₁ = h₁
; h₂ = h₂
; fhA = fhA
; fhB = fhB
}
fixedHeight = IsFiniteHeightWithBotAndDecEq.fixedHeight (Everything.isFiniteHeightIfSupported (everything k) required)
isFiniteHeightLattice = record
{ isLattice = isLattice
; fixedHeight = fixedHeight
}
finiteHeightLattice : FiniteHeightLattice (IterProd k)
finiteHeightLattice = record
{ height = IsFiniteHeightWithBotAndDecEq.height (Everything.isFiniteHeightIfSupported (everything k) required)
; _≈_ = _≈_
lattice : Lattice (IterProd k)
lattice = record
{ _≈_ = _≈_
; _⊔_ = _⊔_
; _⊓_ = _⊓_
; isFiniteHeightLattice = isFiniteHeightLattice
; isLattice = isLattice
}
⊥-built : Height.⊥ fixedHeight (build (Height.⊥ fhA) (Height.⊥ fhB) k)
⊥-built = IsFiniteHeightWithBotAndDecEq.⊥-correct (Everything.isFiniteHeightIfSupported (everything k) required)
module _ {{≈₁-Decidable : IsDecidable _≈₁_}} {{≈₂-Decidable : IsDecidable _≈₂_}}
{h₁ h₂ : }
{{fhA : FixedHeight₁ h₁}} {{fhB : FixedHeight₂ h₂}} where
private
isFiniteHeightWithBotAndDecEq =
Everything.isFiniteHeightIfSupported (everything k)
record
{ ≈₁-Decidable = ≈₁-Decidable
; ≈₂-Decidable = ≈₂-Decidable
; h₁ = h₁
; h₂ = h₂
; fhA = fhA
; fhB = fhB
}
open IsFiniteHeightWithBotAndDecEq isFiniteHeightWithBotAndDecEq using (height; ⊥-correct)
instance
fixedHeight = IsFiniteHeightWithBotAndDecEq.fixedHeight isFiniteHeightWithBotAndDecEq
isFiniteHeightLattice = record
{ isLattice = isLattice
; fixedHeight = fixedHeight
}
finiteHeightLattice : FiniteHeightLattice (IterProd k)
finiteHeightLattice = record
{ height = height
; _≈_ = _≈_
; _⊔_ = _⊔_
; _⊓_ = _⊓_
; isFiniteHeightLattice = isFiniteHeightLattice
}
⊥-built : Height.⊥ fixedHeight (build (Height.⊥ fhA) (Height.⊥ fhB) k)
⊥-built = ⊥-correct

69
Lattice/Map.agda
View File

@@ -1,13 +1,14 @@
open import Lattice
open import Relation.Binary.PropositionalEquality as Eq using (_≡_; refl; sym; trans; cong; subst)
open import Relation.Binary.Definitions using (Decidable)
open import Agda.Primitive using (Level) renaming (_⊔_ to _⊔_)
open import Data.Unit using ()
module Lattice.Map {a b : Level} {A : Set a} {B : Set b}
module Lattice.Map {a b : Level} (A : Set a) (B : Set b)
{_≈₂_ : B B Set b}
{_⊔₂_ : B B B} {_⊓₂_ : B B B}
(≡-dec-A : Decidable (_≡_ {a} {A}))
(lB : IsLattice B _≈₂_ _⊔₂_ _⊓₂_) where
{{≡-Decidable-A : IsDecidable {a} {A} _≡_}}
{{lB : IsLattice B _≈₂_ _⊔₂_ _⊓₂_}}
(dummy : ) where
open import Data.List.Membership.Propositional as MemProp using () renaming (_∈_ to _∈ˡ_)
@@ -23,6 +24,8 @@ open import Utils using (Unique; push; Unique-append; All¬-¬Any; All-x∈xs)
open import Data.String using () renaming (_++_ to _++ˢ_)
open import Showable using (Showable; show)
open IsDecidable ≡-Decidable-A using () renaming (R-dec to _≟ᴬ_)
open IsLattice lB using () renaming
( ≈-refl to ≈₂-refl; ≈-sym to ≈₂-sym; ≈-trans to ≈₂-trans
; ≈-⊔-cong to ≈₂-⊔₂-cong; ≈-⊓-cong to ≈₂-⊓₂-cong
@@ -41,7 +44,7 @@ private module ImplKeys where
∈k-dec : (k : A) (l : List (A × B)) Dec (k ∈ˡ (ImplKeys.keys l))
∈k-dec k [] = no (λ ())
∈k-dec k ((k' , v) xs)
with (≡-dec-A k k')
with (k ≟ᴬ k')
... | yes k≡k' = yes (here k≡k')
... | no k≢k' with (∈k-dec k xs)
... | yes k∈kxs = yes (there k∈kxs)
@@ -76,7 +79,7 @@ private module _ where
k∈-dec : (k : A) (l : List A) Dec (k l)
k∈-dec k [] = no (λ ())
k∈-dec k (x xs)
with (≡-dec-A k x)
with (k ≟ᴬ x)
... | yes refl = yes (here refl)
... | no k≢x with (k∈-dec k xs)
... | yes k∈xs = yes (there k∈xs)
@@ -113,7 +116,7 @@ private module ImplInsert (f : B → B → B) where
insert : A B List (A × B) List (A × B)
insert k v [] = (k , v) []
insert k v (x@(k' , v') xs) with ≡-dec-A k k'
insert k v (x@(k' , v') xs) with k ≟ᴬ k'
... | yes _ = (k' , f v v') xs
... | no _ = x insert k v xs
@@ -123,11 +126,11 @@ private module ImplInsert (f : B → B → B) where
insert-keys-∈ : {k : A} {v : B} {l : List (A × B)}
k ∈k l keys l keys (insert k v l)
insert-keys-∈ {k} {v} {(k' , v') xs} (here k≡k')
with (≡-dec-A k k')
with (k ≟ᴬ k')
... | yes _ = refl
... | no k≢k' = ⊥-elim (k≢k' k≡k')
insert-keys-∈ {k} {v} {(k' , _) xs} (there k∈kxs)
with (≡-dec-A k k')
with (k ≟ᴬ k')
... | yes _ = refl
... | no _ = cong (λ xs' k' xs') (insert-keys-∈ k∈kxs)
@@ -135,7 +138,7 @@ private module ImplInsert (f : B → B → B) where
¬ (k ∈k l) (keys l ++ (k [])) keys (insert k v l)
insert-keys-∉ {k} {v} {[]} _ = refl
insert-keys-∉ {k} {v} {(k' , v') xs} k∉kl
with (≡-dec-A k k')
with (k ≟ᴬ k')
... | yes k≡k' = ⊥-elim (k∉kl (here k≡k'))
... | no _ = cong (λ xs' k' xs')
(insert-keys-∉ (λ k∈kxs k∉kl (there k∈kxs)))
@@ -171,7 +174,7 @@ private module ImplInsert (f : B → B → B) where
¬ k ∈k l (k , v) insert k v l
insert-fresh {l = []} k∉kl = here refl
insert-fresh {k} {l = (k' , v') xs} k∉kl
with ≡-dec-A k k'
with k ≟ᴬ k'
... | yes k≡k' = ⊥-elim (k∉kl (here k≡k'))
... | no _ = there (insert-fresh (λ k∈kxs k∉kl (there k∈kxs)))
@@ -180,9 +183,9 @@ private module ImplInsert (f : B → B → B) where
insert-preserves-∉k {l = []} k≢k' k∉kl (here k≡k') = k≢k' k≡k'
insert-preserves-∉k {l = []} k≢k' k∉kl (there ())
insert-preserves-∉k {k} {k'} {v'} {(k'' , v'') xs} k≢k' k∉kl k∈kil
with ≡-dec-A k k''
with k ≟ᴬ k''
... | yes k≡k'' = k∉kl (here k≡k'')
... | no k≢k'' with ≡-dec-A k' k'' | k∈kil
... | no k≢k'' with k' ≟ᴬ k'' | k∈kil
... | yes k'≡k'' | here k≡k'' = k≢k'' k≡k''
... | yes k'≡k'' | there k∈kxs = k∉kl (there k∈kxs)
... | no k'≢k'' | here k≡k'' = k∉kl (here k≡k'')
@@ -193,18 +196,18 @@ private module ImplInsert (f : B → B → B) where
¬ k ∈k l₁ ¬ k ∈k l₂ ¬ k ∈k union l₁ l₂
union-preserves-∉ {l₁ = []} _ k∉kl₂ = k∉kl₂
union-preserves-∉ {k} {(k' , v') xs₁} k∉kl₁ k∉kl₂
with ≡-dec-A k k'
with k ≟ᴬ k'
... | yes k≡k' = ⊥-elim (k∉kl₁ (here k≡k'))
... | no k≢k' = insert-preserves-∉k k≢k' (union-preserves-∉ (λ k∈kxs₁ k∉kl₁ (there k∈kxs₁)) k∉kl₂)
insert-preserves-∈k : {k k' : A} {v' : B} {l : List (A × B)}
k ∈k l k ∈k insert k' v' l
insert-preserves-∈k {k} {k'} {v'} {(k'' , v'') xs} (here k≡k'')
with (≡-dec-A k' k'')
with k' ≟ᴬ k''
... | yes _ = here k≡k''
... | no _ = here k≡k''
insert-preserves-∈k {k} {k'} {v'} {(k'' , v'') xs} (there k∈kxs)
with (≡-dec-A k' k'')
with k' ≟ᴬ k''
... | yes _ = there k∈kxs
... | no _ = there (insert-preserves-∈k k∈kxs)
@@ -236,11 +239,11 @@ private module ImplInsert (f : B → B → B) where
insert-preserves-∈ : {k k' : A} {v v' : B} {l : List (A × B)}
¬ k k' (k , v) l (k , v) insert k' v' l
insert-preserves-∈ {k} {k'} {l = x xs} k≢k' (here k,v=x)
rewrite sym k,v=x with ≡-dec-A k' k
rewrite sym k,v=x with k' ≟ᴬ k
... | yes k'≡k = ⊥-elim (k≢k' (sym k'≡k))
... | no _ = here refl
insert-preserves-∈ {k} {k'} {l = (k'' , _) xs} k≢k' (there k,v∈xs)
with ≡-dec-A k' k''
with k' ≟ᴬ k''
... | yes _ = there k,v∈xs
... | no _ = there (insert-preserves-∈ k≢k' k,v∈xs)
@@ -259,7 +262,7 @@ private module ImplInsert (f : B → B → B) where
k,v∈mxs₁l = union-preserves-∈₁ uxs₁ k,v∈xs₁ k∉kl₂
k≢k' : ¬ k k'
k≢k' with ≡-dec-A k k'
k≢k' with k ≟ᴬ k'
... | yes k≡k' rewrite k≡k' = ⊥-elim (All¬-¬Any k'≢xs₁ (∈-cong proj₁ k,v∈xs₁))
... | no k≢k' = k≢k'
union-preserves-∈₁ {l₁ = (k' , v') xs₁} (push k'≢xs₁ uxs₁) (here k,v≡k',v') k∉kl₂
@@ -270,11 +273,11 @@ private module ImplInsert (f : B → B → B) where
Unique (keys l) (k , v') l (k , f v v') (insert k v l)
insert-combines {l = (k' , v'') xs} _ (here k,v'≡k',v'')
rewrite cong proj₁ k,v'≡k',v'' rewrite cong proj₂ k,v'≡k',v''
with ≡-dec-A k' k'
with k' ≟ᴬ k'
... | yes _ = here refl
... | no k≢k' = ⊥-elim (k≢k' refl)
insert-combines {k} {l = (k' , v'') xs} (push k'≢xs uxs) (there k,v'∈xs)
with ≡-dec-A k k'
with k ≟ᴬ k'
... | yes k≡k' rewrite k≡k' = ⊥-elim (All¬-¬Any k'≢xs (∈-cong proj₁ k,v'∈xs))
... | no k≢k' = there (insert-combines uxs k,v'∈xs)
@@ -288,13 +291,13 @@ private module ImplInsert (f : B → B → B) where
insert-preserves-∈ k≢k' (union-combines uxs₁ ul₂ k,v₁∈xs₁ k,v₂∈l₂)
where
k≢k' : ¬ k k'
k≢k' with ≡-dec-A k k'
k≢k' with k ≟ᴬ k'
... | yes k≡k' rewrite k≡k' = ⊥-elim (All¬-¬Any k'≢xs₁ (∈-cong proj₁ k,v₁∈xs₁))
... | no k≢k' = k≢k'
update : A B List (A × B) List (A × B)
update k v [] = []
update k v ((k' , v') xs) with ≡-dec-A k k'
update k v ((k' , v') xs) with k ≟ᴬ k'
... | yes _ = (k' , f v v') xs
... | no _ = (k' , v') update k v xs
@@ -314,7 +317,7 @@ private module ImplInsert (f : B → B → B) where
keys l keys (update k v l)
update-keys {l = []} = refl
update-keys {k} {v} {l = (k' , v') xs}
with ≡-dec-A k k'
with k ≟ᴬ k'
... | yes _ = refl
... | no _ rewrite update-keys {k} {v} {xs} = refl
@@ -431,11 +434,11 @@ private module ImplInsert (f : B → B → B) where
¬ k k' (k , v) l (k , v) update k' v' l
update-preserves-∈ {k} {k'} {v} {v'} {(k'' , v'') xs} k≢k' (here k,v≡k'',v'')
rewrite cong proj₁ k,v≡k'',v'' rewrite cong proj₂ k,v≡k'',v''
with ≡-dec-A k' k''
with k' ≟ᴬ k''
... | yes k'≡k'' = ⊥-elim (k≢k' (sym k'≡k''))
... | no _ = here refl
update-preserves-∈ {k} {k'} {v} {v'} {(k'' , v'') xs} k≢k' (there k,v∈xs)
with ≡-dec-A k' k''
with k' ≟ᴬ k''
... | yes _ = there k,v∈xs
... | no _ = there (update-preserves-∈ k≢k' k,v∈xs)
@@ -449,11 +452,11 @@ private module ImplInsert (f : B → B → B) where
Unique (keys l) (k , v) l (k , f v' v) update k v' l
update-combines {k} {v} {v'} {(k' , v'') xs} _ (here k,v=k',v'')
rewrite cong proj₁ k,v=k',v'' rewrite cong proj₂ k,v=k',v''
with ≡-dec-A k' k'
with k' ≟ᴬ k'
... | yes _ = here refl
... | no k'≢k' = ⊥-elim (k'≢k' refl)
update-combines {k} {v} {v'} {(k' , v'') xs} (push k'≢xs uxs) (there k,v∈xs)
with ≡-dec-A k k'
with k ≟ᴬ k'
... | yes k≡k' rewrite k≡k' = ⊥-elim (All¬-¬Any k'≢xs (∈-cong proj₁ k,v∈xs))
... | no _ = there (update-combines uxs k,v∈xs)
@@ -467,7 +470,7 @@ private module ImplInsert (f : B → B → B) where
update-preserves-∈ k≢k' (updates-combine uxs₁ u₂ k,v₁∈xs k,v₂∈l₂)
where
k≢k' : ¬ k k'
k≢k' with ≡-dec-A k k'
k≢k' with k ≟ᴬ k'
... | yes k≡k' rewrite k≡k' = ⊥-elim (All¬-¬Any k'≢xs (∈-cong proj₁ k,v₁∈xs))
... | no k≢k' = k≢k'
@@ -625,7 +628,8 @@ Expr-Provenance-≡ {k} {v} e k,v∈e
with (v' , (p , k,v'∈e)) Expr-Provenance k e (forget k,v∈e)
rewrite Map-functional {m = e } k,v∈e k,v'∈e = p
module _ (≈₂-dec : IsDecidable _≈₂_) where
module _ {{≈₂-Decidable : IsDecidable _≈₂_}} where
open IsDecidable ≈₂-Decidable using () renaming (R-dec to ≈₂-dec)
private module _ where
data SubsetInfo (m₁ m₂ : Map) : Set (a ⊔ℓ b) where
extra : (k : A) k ∈k m₁ ¬ k ∈k m₂ SubsetInfo m₁ m₂
@@ -676,6 +680,9 @@ module _ (≈₂-dec : IsDecidable _≈₂_) where
... | _ | no m₂̷⊆m₁ = no (λ (_ , m₂⊆m₁) m₂̷⊆m₁ m₂⊆m₁)
... | no m₁̷⊆m₂ | _ = no (λ (m₁⊆m₂ , _) m₁̷⊆m₂ m₁⊆m₂)
≈-Decidable : IsDecidable _≈_
≈-Decidable = record { R-dec = ≈-dec }
private module I = ImplInsert _⊔₂_
private module I = ImplInsert _⊓₂_
@@ -1026,7 +1033,7 @@ updating-via-k∉ks-backward m = transform-k∉ks-backward
module _ {l} {L : Set l}
{_≈ˡ_ : L L Set l} {_⊔ˡ_ : L L L} {_⊓ˡ_ : L L L}
(lL : IsLattice L _≈ˡ_ _⊔ˡ_ _⊓ˡ_) where
{{lL : IsLattice L _≈ˡ_ _⊔ˡ_ _⊓ˡ_}} where
open IsLattice lL using () renaming (_≼_ to _≼ˡ_)
module _ (f : L Map) (f-Monotonic : Monotonic _≼ˡ_ _≼_ f)

6
Lattice/MapSet.agda
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@@ -1,9 +1,9 @@
open import Lattice
open import Relation.Binary.PropositionalEquality as Eq using (_≡_; refl; sym; trans; cong; subst)
open import Relation.Binary.Definitions using (Decidable)
open import Agda.Primitive using (Level) renaming (_⊔_ to _⊔_)
open import Data.Unit using ()
module Lattice.MapSet {a : Level} {A : Set a} (≡-dec-A : Decidable (_≡_ {a} {A})) where
module Lattice.MapSet {a : Level} (A : Set a) {{≡-Decidable-A : IsDecidable (_≡_ {a} {A})}} (dummy : ) where
open import Data.List using (List; map)
open import Data.Product using (_,_; proj₁)
@@ -12,7 +12,7 @@ open import Function using (_∘_)
open import Lattice.Unit using (; tt) renaming (_≈_ to _≈₂_; _⊔_ to _⊔₂_; _⊓_ to _⊓₂_; isLattice to -isLattice)
import Lattice.Map
private module UnitMap = Lattice.Map ≡-dec-A -isLattice
private module UnitMap = Lattice.Map A dummy
open UnitMap
using (Map; Expr; ⟦_⟧)
renaming

74
Lattice/Nat.agda
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@@ -18,31 +18,32 @@ private
≡-⊓-cong : {a₁ a₂ a₃ a₄} a₁ a₂ a₃ a₄ (a₁ a₃) (a₂ a₄)
≡-⊓-cong a₁≡a₂ a₃≡a₄ rewrite a₁≡a₂ rewrite a₃≡a₄ = refl
isMaxSemilattice : IsSemilattice _≡_ _⊔_
isMaxSemilattice = record
{ ≈-equiv = record
{ ≈-refl = refl
; ≈-sym = sym
; ≈-trans = trans
instance
isMaxSemilattice : IsSemilattice _≡_ _⊔_
isMaxSemilattice = record
{ ≈-equiv = record
{ ≈-refl = refl
; ≈-sym = sym
; ≈-trans = trans
}
; ≈-⊔-cong = ≡-⊔-cong
; ⊔-assoc = ⊔-assoc
; ⊔-comm = ⊔-comm
; ⊔-idemp = ⊔-idem
}
; ≈-⊔-cong = ≡-⊔-cong
; ⊔-assoc = ⊔-assoc
; ⊔-comm = ⊔-comm
; ⊔-idemp = ⊔-idem
}
isMinSemilattice : IsSemilattice _≡_ _⊓_
isMinSemilattice = record
{ ≈-equiv = record
{ ≈-refl = refl
; ≈-sym = sym
; ≈-trans = trans
isMinSemilattice : IsSemilattice _≡_ _⊓_
isMinSemilattice = record
{ ≈-equiv = record
{ ≈-refl = refl
; ≈-sym = sym
; ≈-trans = trans
}
; ≈-⊔-cong = ≡-⊓-cong
; ⊔-assoc = ⊓-assoc
; ⊔-comm = ⊓-comm
; ⊔-idemp = ⊓-idem
}
; ≈-⊔-cong = ≡-⊓-cong
; ⊔-assoc = ⊓-assoc
; ⊔-comm = ⊓-comm
; ⊔-idemp = ⊓-idem
}
private
max-bound₁ : {x y z : } x y z x z
@@ -74,18 +75,19 @@ private
helper : x (x y) x x x x x x (x y) x
helper x⊔x⊓y≤x⊔x x⊔x≡x rewrite x⊔x≡x = x⊔x⊓y≤x⊔x
isLattice : IsLattice _≡_ _⊔_ _⊓_
isLattice = record
{ joinSemilattice = isMaxSemilattice
; meetSemilattice = isMinSemilattice
; absorb-⊔-⊓ = λ x y maxmin-absorb {x} {y}
; absorb-⊓- = λ x y minmax-absorb {x} {y}
}
instance
isLattice : IsLattice _≡_ _⊔_ _⊓_
isLattice = record
{ joinSemilattice = isMaxSemilattice
; meetSemilattice = isMinSemilattice
; absorb-⊔-⊓ = λ x y maxmin-absorb {x} {y}
; absorb-⊓-⊔ = λ x y minmax-absorb {x} {y}
}
lattice : Lattice
lattice = record
{ _≈_ = _≡_
; _⊔_ = _⊔_
; _⊓_ = _⊓_
; isLattice = isLattice
}
lattice : Lattice
lattice = record
{ _≈_ = _≡_
; _⊔_ = _⊔_
; _⊓_ = _⊓_
; isLattice = isLattice
}

210
Lattice/Prod.agda
View File

@@ -1,10 +1,10 @@
open import Lattice
module Lattice.Prod {a b} {A : Set a} {B : Set b}
(_≈₁_ : A A Set a) (_≈₂_ : B B Set b)
(_⊔₁_ : A A A) (_⊔₂_ : B B B)
(_⊓₁_ : A A A) (_⊓₂_ : B B B)
(lA : IsLattice A _≈₁_ _⊔₁_ _⊓₁_) (lB : IsLattice B _≈₂_ _⊔₂_ _⊓₂_) where
module Lattice.Prod {a b} (A : Set a) (B : Set b)
{_≈₁_ : A A Set a} {_≈₂_ : B B Set b}
{_⊔₁_ : A A A} {_⊔₂_ : B B B}
{_⊓₁_ : A A A} {_⊓₂_ : B B B}
{{lA : IsLattice A _≈₁_ _⊔₁_ _⊓₁_}} {{lB : IsLattice B _≈₂_ _⊔₂_ _⊓₂_}} where
open import Agda.Primitive using (Level) renaming (_⊔_ to _⊔_)
open import Data.Nat using (; _≤_; _+_; suc)
@@ -12,6 +12,7 @@ open import Data.Product using (_×_; Σ; _,_; proj₁; proj₂)
open import Data.Empty using (⊥-elim)
open import Relation.Binary.Core using (_Preserves_⟶_ )
open import Relation.Binary.PropositionalEquality using (sym; subst)
open import Relation.Binary.Definitions using (Decidable)
open import Relation.Nullary using (¬_; yes; no)
open import Equivalence
import Chain
@@ -39,13 +40,14 @@ open IsLattice lB using () renaming
_≈_ : A × B A × B Set (a ⊔ℓ b)
(a₁ , b₁) (a₂ , b₂) = (a₁ ≈₁ a₂) × (b₁ ≈₂ b₂)
≈-equiv : IsEquivalence (A × B) _≈_
≈-equiv = record
{ ≈-refl = λ {p} (≈₁-refl , ≈₂-refl)
; ≈-sym = λ {p₁} {p₂} (a₁≈a₂ , b₁≈b₂) (≈₁-sym a₁≈a₂ , ≈₂-sym b₁≈b₂)
; ≈-trans = λ {p₁} {p₂} {p₃} (a₁≈a₂ , b₁≈b₂) (a₂≈a , b₂≈b)
( -trans a₁≈a₂ a₂≈a , ≈₂-trans b₁≈b₂ b₂≈b₃ )
}
instance
≈-equiv : IsEquivalence (A × B) _≈_
≈-equiv = record
{ ≈-refl = λ {p} (≈₁-refl , ≈₂-refl)
; ≈-sym = λ {p₁} {p₂} (a₁≈a₂ , b₁≈b₂) (≈₁-sym a₁≈a , ≈₂-sym b₁≈b)
; ≈-trans = λ {p₁} {p₂} {p₃} (a₁≈a , b₁≈b₂) (a₂≈a₃ , b₂≈b₃)
( ≈₁-trans a₁≈a₂ a₂≈a₃ , ≈₂-trans b₁≈b₂ b₂≈b₃ )
}
_⊔_ : A × B A × B A × B
(a₁ , b₁) (a₂ , b₂) = (a₁ ⊔₁ a₂ , b₁ ⊔₂ b₂)
@@ -75,116 +77,124 @@ private module ProdIsSemilattice (f₁ : A → A → A) (f₂ : B → B → B) (
)
}
isJoinSemilattice : IsSemilattice (A × B) _≈_ _⊔_
isJoinSemilattice = ProdIsSemilattice.isSemilattice _⊔₁_ _⊔₂_ joinSemilattice₁ joinSemilattice₂
instance
isJoinSemilattice : IsSemilattice (A × B) _≈_ _⊔_
isJoinSemilattice = ProdIsSemilattice.isSemilattice _⊔₁_ _⊔₂_ joinSemilattice₁ joinSemilattice₂
isMeetSemilattice : IsSemilattice (A × B) _≈_ _⊓_
isMeetSemilattice = ProdIsSemilattice.isSemilattice _⊓₁_ _⊓₂_ meetSemilattice₁ meetSemilattice₂
isMeetSemilattice : IsSemilattice (A × B) _≈_ _⊓_
isMeetSemilattice = ProdIsSemilattice.isSemilattice _⊓₁_ _⊓₂_ meetSemilattice₁ meetSemilattice₂
isLattice : IsLattice (A × B) _≈_ _⊔_ _⊓_
isLattice = record
{ joinSemilattice = isJoinSemilattice
; meetSemilattice = isMeetSemilattice
; absorb-⊔-⊓ = λ (a₁ , b₁) (a₂ , b₂)
( IsLattice.absorb-⊔-⊓ lA a₁ a₂
, IsLattice.absorb-⊔-⊓ lB b₁ b₂
)
; absorb-⊓-⊔ = λ (a₁ , b₁) (a₂ , b₂)
( IsLattice.absorb-⊓-⊔ lA a₁ a₂
, IsLattice.absorb-⊓-⊔ lB b₁ b₂
)
}
isLattice : IsLattice (A × B) _≈_ _⊔_ _⊓_
isLattice = record
{ joinSemilattice = isJoinSemilattice
; meetSemilattice = isMeetSemilattice
; absorb-⊔-⊓ = λ (a₁ , b₁) (a₂ , b₂)
( IsLattice.absorb-⊔-⊓ lA a₁ a₂
, IsLattice.absorb-⊔-⊓ lB b₁ b₂
)
; absorb-⊓-⊔ = λ (a₁ , b₁) (a₂ , b₂)
( IsLattice.absorb-⊓-⊔ lA a₁ a₂
, IsLattice.absorb-⊓-⊔ lB b₁ b₂
)
}
lattice : Lattice (A × B)
lattice = record
{ _≈_ = _≈_
; _⊔_ = _⊔_
; _⊓_ = _⊓_
; isLattice = isLattice
}
lattice : Lattice (A × B)
lattice = record
{ _≈_ = _≈_
; _⊔_ = _⊔_
; _⊓_ = _⊓_
; isLattice = isLattice
}
module _ (≈₁-dec : IsDecidable _≈₁_) (≈₂-dec : IsDecidable _≈₂_) where
≈-dec : IsDecidable _≈_
open IsLattice isLattice using (_≼_; _≺_; ≺-cong) public
module _ {{≈₁-Decidable : IsDecidable _≈₁_}} {{≈₂-Decidable : IsDecidable _≈₂_}} where
open IsDecidable ≈₁-Decidable using () renaming (R-dec to ≈₁-dec)
open IsDecidable ≈₂-Decidable using () renaming (R-dec to ≈₂-dec)
≈-dec : Decidable _≈_
≈-dec (a₁ , b₁) (a₂ , b₂)
with ≈₁-dec a₁ a₂ | ≈₂-dec b₁ b₂
... | yes a₁≈a₂ | yes b₁≈b₂ = yes (a₁≈a₂ , b₁≈b₂)
... | no a₁̷≈a₂ | _ = no (λ (a₁≈a₂ , _) a₁̷≈a₂ a₁≈a₂)
... | _ | no b₁̷≈b₂ = no (λ (_ , b₁≈b₂) b₁̷≈b₂ b₁≈b₂)
instance
≈-Decidable : IsDecidable _≈_
≈-Decidable = record { R-dec = ≈-dec }
module _ (≈₁-dec : IsDecidable _≈₁_) (≈₂-dec : IsDecidable _≈₂_)
(h₁ h₂ : )
(fhA : FixedHeight₁ h₁) (fhB : FixedHeight₂ h₂) where
module _ {h h₂ : }
{{fhA : FixedHeight₁ h₁}} {{fhB : FixedHeight₂ h₂}} where
open import Data.Nat.Properties
open IsLattice isLattice using (_≼_; _≺_; ≺-cong)
open import Data.Nat.Properties
module ChainMapping = ChainMapping joinSemilattice₁ isJoinSemilattice
module ChainMapping = ChainMapping joinSemilattice₂ isJoinSemilattice
module ChainMapping = ChainMapping joinSemilattice₁ isJoinSemilattice
module ChainMapping = ChainMapping joinSemilattice₂ isJoinSemilattice
module ChainA = Chain _≈₁_ ≈₁-equiv _≺₁_ ≺₁-cong
module ChainB = Chain _≈₂_ ≈₂-equiv _≺₂_ ≺₂-cong
module ProdChain = Chain _≈_ ≈-equiv _≺_ ≺-cong
module ChainA = Chain _≈₁_ ≈₁-equiv _≺₁_ ≺₁-cong
module ChainB = Chain _≈₂_ ≈₂-equiv _≺₂_ ≺₂-cong
module ProdChain = Chain _≈_ ≈-equiv _≺_ ≺-cong
open ChainA using () renaming (Chain to Chain₁; done to done₁; step to step₁; Chain-≈-cong₁ to Chain₁-≈-cong₁)
open ChainB using () renaming (Chain to Chain₂; done to done₂; step to step₂; Chain-≈-cong₁ to Chain₂-≈-cong₁)
open ProdChain using (Chain; concat; done; step)
open ChainA using () renaming (Chain to Chain₁; done to done₁; step to step₁; Chain-≈-cong₁ to Chain₁-≈-cong₁)
open ChainB using () renaming (Chain to Chain₂; done to done₂; step to step₂; Chain-≈-cong₁ to Chain₂-≈-cong₁)
open ProdChain using (Chain; concat; done; step)
private
a,∙-Monotonic : (a : A) Monotonic _≼₂_ _≼_ (λ b (a , b))
a,∙-Monotonic a {b₁} {b₂} b₁⊔b₂≈b₂ = (⊔₁-idemp a , b₁⊔b₂≈b₂)
private
a,∙-Monotonic : (a : A) Monotonic _≼₂_ _≼_ (λ b (a , b))
a,∙-Monotonic a {b₁} {b₂} b₁⊔b₂≈b₂ = (⊔₁-idemp a , b₁⊔b₂≈b₂)
a,∙-Preserves-≈₂ : (a : A) (λ b (a , b)) Preserves _≈₂_ _≈_
a,∙-Preserves-≈₂ a {b₁} {b₂} b₁≈b₂ = (≈₁-refl , b₁≈b₂)
a,∙-Preserves-≈₂ : (a : A) (λ b (a , b)) Preserves _≈₂_ _≈_
a,∙-Preserves-≈₂ a {b₁} {b₂} b₁≈b₂ = (≈₁-refl , b₁≈b₂)
∙,b-Monotonic : (b : B) Monotonic _≼₁_ _≼_ (λ a (a , b))
∙,b-Monotonic b {a₁} {a₂} a₁⊔a₂≈a₂ = (a₁⊔a₂≈a₂ , ⊔₂-idemp b)
∙,b-Monotonic : (b : B) Monotonic _≼₁_ _≼_ (λ a (a , b))
∙,b-Monotonic b {a₁} {a₂} a₁⊔a₂≈a₂ = (a₁⊔a₂≈a₂ , ⊔₂-idemp b)
∙,b-Preserves-≈₁ : (b : B) (λ a (a , b)) Preserves _≈₁_ _≈_
∙,b-Preserves-≈₁ b {a₁} {a₂} a₁≈a₂ = (a₁≈a₂ , ≈₂-refl)
∙,b-Preserves-≈₁ : (b : B) (λ a (a , b)) Preserves _≈₁_ _≈_
∙,b-Preserves-≈₁ b {a₁} {a₂} a₁≈a₂ = (a₁≈a₂ , ≈₂-refl)
open ChainA.Height fhA using () renaming ( to ⊥₁; to ⊤₁; longestChain to longestChain₁; bounded to bounded₁)
open ChainB.Height fhB using () renaming ( to ⊥₂; to ⊤₂; longestChain to longestChain₂; bounded to bounded₂)
open ChainA.Height fhA using () renaming ( to ⊥₁; to ⊤₁; longestChain to longestChain₁; bounded to bounded₁)
open ChainB.Height fhB using () renaming ( to ⊥₂; to ⊤₂; longestChain to longestChain₂; bounded to bounded₂)
unzip : {a₁ a₂ : A} {b₁ b₂ : B} {n : } Chain (a₁ , b₁) (a₂ , b₂) n Σ ( × ) (λ (n₁ , n₂) ((Chain₁ a₁ a₂ n₁ × Chain₂ b₁ b₂ n₂) × (n n₁ + n₂)))
unzip (done (a₁≈a₂ , b₁≈b₂)) = ((0 , 0) , ((done₁ a₁≈a₂ , done₂ b₁≈b₂) , ≤-refl))
unzip {a₁} {a₂} {b₁} {b₂} {n} (step {(a₁ , b₁)} {(a , b)} ((a₁≼a , b₁≼b) , a₁b₁̷≈ab) (a≈a' , b≈b') a'b'a₂b₂)
with ≈₁-dec a₁ a | ≈₂-dec b₁ b | unzip a'b'a₂b₂
... | yes a₁≈a | yes b₁≈b | ((n₁ , n₂) , ((c₁ , c₂) , n≤n₁+n₂)) = ⊥-elim (a₁b₁̷≈ab (a₁≈a , b₁≈b))
... | no a₁̷≈a | yes b₁≈b | ((n₁ , n₂) , ((c₁ , c₂) , n≤n₁+n₂)) =
((suc n₁ , n₂) , ((step₁ (a₁≼a , a₁̷≈a) a≈a' c₁ , Chain₂-≈-cong₁ (≈₂-sym (≈₂-trans b₁≈b b≈b')) c₂), +-monoʳ-≤ 1 (n≤n₁+n₂)))
... | yes a₁≈a | no b₁̷≈b | ((n₁ , n₂) , ((c₁ , c₂) , n≤n₁+n₂)) =
((n₁ , suc n₂) , ( (Chain₁-≈-cong₁ (≈₁-sym (≈₁-trans a₁≈a a≈a')) c₁ , step₂ (b₁≼b , b₁̷≈b) b≈b' c₂)
, subst (n ≤_) (sym (+-suc n₁ n₂)) (+-monoʳ-≤ 1 n≤n₁+n₂)
))
... | no a₁̷≈a | no b₁̷≈b | ((n₁ , n₂) , ((c₁ , c₂) , n≤n₁+n₂)) =
((suc n₁ , suc n₂) , ( (step₁ (a₁≼a , a₁̷≈a) a≈a' c₁ , step₂ (b₁≼b , b₁̷≈b) b≈b' c₂)
, m≤n⇒m≤o+n 1 (subst (n ≤_) (sym (+-suc n₁ n₂)) (+-monoʳ-≤ 1 n≤n₁+n₂))
unzip : {a₁ a₂ : A} {b₁ b₂ : B} {n : } Chain (a₁ , b₁) (a₂ , b₂) n Σ ( × ) (λ (n₁ , n₂) ((Chain₁ a₁ a₂ n₁ × Chain₂ b₁ b₂ n₂) × (n n₁ + n₂)))
unzip (done (a₁≈a₂ , b₁≈b₂)) = ((0 , 0) , ((done₁ a₁≈a₂ , done₂ b₁≈b₂) , ≤-refl))
unzip {a₁} {a₂} {b₁} {b₂} {n} (step {(a₁ , b₁)} {(a , b)} ((a₁≼a , b₁≼b) , a₁b₁̷≈ab) (a≈a' , b≈b') a'b'a₂b₂)
with ≈₁-dec a₁ a | ≈₂-dec b₁ b | unzip a'b'a₂b₂
... | yes a₁≈a | yes b₁≈b | ((n₁ , n₂) , ((c₁ , c₂) , n≤n₁+n₂)) = ⊥-elim (a₁b₁̷≈ab (a₁≈a , b₁≈b))
... | no a₁̷≈a | yes b₁≈b | ((n₁ , n₂) , ((c₁ , c₂) , n≤n₁+n₂)) =
((suc n₁ , n₂) , ((step₁ (a₁≼a , a₁̷≈a) a≈a' c₁ , Chain₂-≈-cong₁ (≈₂-sym (≈₂-trans b₁≈b b≈b')) c₂), +-monoʳ-≤ 1 (n≤n₁+n₂)))
... | yes a₁≈a | no b₁̷≈b | ((n₁ , n₂) , ((c₁ , c₂) , n≤n₁+n₂)) =
((n₁ , suc n₂) , ( (Chain₁-≈-cong₁ (≈₁-sym (≈₁-trans a₁≈a a≈a')) c₁ , step₂ (b₁≼b , b₁̷≈b) b≈b' c₂)
, subst (n ≤_) (sym (+-suc n₁ n₂)) (+-monoʳ-≤ 1 n≤n₁+n₂)
))
... | no a₁̷≈a | no b₁̷≈b | ((n₁ , n₂) , ((c₁ , c₂) , n≤n₁+n₂)) =
((suc n₁ , suc n₂) , ( (step₁ (a₁≼a , a₁̷≈a) a≈a' c₁ , step₂ (b₁≼b , b₁̷≈b) b≈b' c₂)
, m≤n⇒m≤o+n 1 (subst (n ≤_) (sym (+-suc n₁ n₂)) (+-monoʳ-≤ 1 n≤n₁+n₂))
))
fixedHeight : IsLattice.FixedHeight isLattice (h₁ + h₂)
fixedHeight = record
{ = (⊥₁ , ⊥₂)
; = ( , )
; longestChain = concat
(ChainMapping₁.Chain-map (λ a (a , ⊥₂)) (∙,b-Monotonic _) proj₁ (∙,b-Preserves-≈₁ _) longestChain₁)
(ChainMapping.Chain-map (λ b (⊤₁ , b)) (a,∙-Monotonic _) proj (a,∙-Preserves-≈ _) longestChain)
; bounded = λ a₁b₁a₂b₂
let ((n₁ , n₂) , ((a₁a₂ , b₁b₂) , n≤n₁+n₂)) = unzip a₁b₁a₂b₂
in ≤-trans n≤n₁+n₂ (+-mono-≤ (bounded₁ a₁a₂) (bounded₂ b₁b₂))
}
instance
fixedHeight : IsLattice.FixedHeight isLattice (h₁ + h₂)
fixedHeight = record
{ = ( , )
; = (⊤₁ , ⊤₂)
; longestChain = concat
(ChainMapping.Chain-map (λ a (a , ⊥₂)) (,b-Monotonic _) proj (,b-Preserves-≈ _) longestChain)
(ChainMapping₂.Chain-map (λ b (⊤₁ , b)) (a,∙-Monotonic _) proj₂ (a,∙-Preserves-≈₂ _) longestChain₂)
; bounded = λ a₁b₁a₂b₂
let ((n₁ , n₂) , ((a₁a₂ , b₁b₂) , n≤n₁+n₂)) = unzip a₁b₁a₂b₂
in ≤-trans n≤n₁+n₂ (+-mono-≤ (bounded₁ a₁a₂) (bounded₂ b₁b₂))
}
isFiniteHeightLattice : IsFiniteHeightLattice (A × B) (h₁ + h₂) _≈_ _⊔_ _⊓_
isFiniteHeightLattice = record
{ isLattice = isLattice
; fixedHeight = fixedHeight
}
isFiniteHeightLattice : IsFiniteHeightLattice (A × B) (h₁ + h₂) _≈_ _⊔_ _⊓_
isFiniteHeightLattice = record
{ isLattice = isLattice
; fixedHeight = fixedHeight
}
finiteHeightLattice : FiniteHeightLattice (A × B)
finiteHeightLattice = record
{ height = h₁ + h₂
; _≈_ = _≈_
; _⊔_ = _⊔_
; _⊓_ = _⊓_
; isFiniteHeightLattice = isFiniteHeightLattice
}
finiteHeightLattice : FiniteHeightLattice (A × B)
finiteHeightLattice = record
{ height = h₁ + h₂
; _≈_ = _≈_
; _⊔_ = _⊔_
; _⊓_ = _⊓_
; isFiniteHeightLattice = isFiniteHeightLattice
}

117
Lattice/Unit.agda
View File

@@ -7,6 +7,7 @@ open import Data.Unit using (; tt) public
open import Data.Unit.Properties using (_≟_; ≡-setoid)
open import Relation.Binary using (Setoid)
open import Relation.Binary.PropositionalEquality as Eq using (_≡_)
open import Relation.Binary.Definitions using (Decidable)
open import Relation.Nullary using (Dec; ¬_; yes; no)
open import Equivalence
open import Lattice
@@ -24,9 +25,13 @@ _≈_ = _≡_
; ≈-trans = trans
}
≈-dec : IsDecidable _≈_
≈-dec : Decidable _≈_
≈-dec = _≟_
instance
≈-Decidable : IsDecidable _≈_
≈-Decidable = record { R-dec = ≈-dec }
_⊔_ :
tt tt = tt
@@ -45,14 +50,15 @@ tt ⊓ tt = tt
⊔-idemp : (x : ) (x x) x
⊔-idemp tt = Eq.refl
isJoinSemilattice : IsSemilattice _≈_ _⊔_
isJoinSemilattice = record
{ ≈-equiv = ≈-equiv
; ≈-⊔-cong = ≈-⊔-cong
; ⊔-assoc = ⊔-assoc
; ⊔-comm = ⊔-comm
; ⊔-idemp = ⊔-idemp
}
instance
isJoinSemilattice : IsSemilattice _≈_ _⊔_
isJoinSemilattice = record
{ ≈-equiv = ≈-equiv
; ≈-⊔-cong = ≈-⊔-cong
; ⊔-assoc = ⊔-assoc
; ⊔-comm = ⊔-comm
; ⊔-idemp = ⊔-idemp
}
≈-⊓-cong : {ab₁ ab₂ ab₃ ab₄} ab₁ ab₂ ab₃ ab₄ (ab₁ ab₃) (ab₂ ab₄)
≈-⊓-cong {tt} {tt} {tt} {tt} _ _ = Eq.refl
@@ -66,36 +72,32 @@ isJoinSemilattice = record
⊓-idemp : (x : ) (x x) x
⊓-idemp tt = Eq.refl
isMeetSemilattice : IsSemilattice _≈_ _⊓_
isMeetSemilattice = record
{ ≈-equiv = ≈-equiv
; ≈-⊔-cong = ≈-⊓-cong
; ⊔-assoc = ⊓-assoc
; ⊔-comm = ⊓-comm
; ⊔-idemp = ⊓-idemp
}
instance
isMeetSemilattice : IsSemilattice _≈_ _⊓_
isMeetSemilattice = record
{ ≈-equiv = ≈-equiv
; ≈-⊔-cong = ≈-⊓-cong
; ⊔-assoc = ⊓-assoc
; ⊔-comm = ⊓-comm
; ⊔-idemp = ⊓-idemp
}
absorb-⊔-⊓ : (x y : ) (x (x y)) x
absorb-⊔-⊓ tt tt = Eq.refl
instance
isLattice : IsLattice _≈_ _⊔_ _⊓_
isLattice = record
{ joinSemilattice = isJoinSemilattice
; meetSemilattice = isMeetSemilattice
; absorb-⊔-⊓ = λ { tt tt Eq.refl }
; absorb-⊓-⊔ = λ { tt tt Eq.refl }
}
absorb-⊓-⊔ : (x y : ) (x (x y)) x
absorb-⊓-⊔ tt tt = Eq.refl
isLattice : IsLattice _≈_ _⊔_ _⊓_
isLattice = record
{ joinSemilattice = isJoinSemilattice
; meetSemilattice = isMeetSemilattice
; absorb-⊔-⊓ = absorb-⊔-⊓
; absorb-⊓-⊔ = absorb-⊓-⊔
}
lattice : Lattice
lattice = record
{ _≈_ = _≈_
; _⊔_ = _⊔_
; _⊓_ = _⊓_
; isLattice = isLattice
}
lattice : Lattice
lattice = record
{ _≈_ = _≈_
; _⊔_ = _⊔_
; _⊓_ = _⊓_
; isLattice = isLattice
}
open Chain _≈_ ≈-equiv (IsLattice._≺_ isLattice) (IsLattice.≺-cong isLattice)
@@ -107,25 +109,26 @@ private
isLongest {tt} {tt} (step (tt⊔tt≈tt , tt̷≈tt) _ _) = ⊥-elim (tt̷≈tt refl)
isLongest (done _) = z≤n
fixedHeight : IsLattice.FixedHeight isLattice 0
fixedHeight = record
{ = tt
; = tt
; longestChain = longestChain
; bounded = isLongest
}
instance
fixedHeight : IsLattice.FixedHeight isLattice 0
fixedHeight = record
{ = tt
; = tt
; longestChain = longestChain
; bounded = isLongest
}
isFiniteHeightLattice : IsFiniteHeightLattice 0 _≈_ _⊔_ _⊓_
isFiniteHeightLattice = record
{ isLattice = isLattice
; fixedHeight = fixedHeight
}
isFiniteHeightLattice : IsFiniteHeightLattice 0 _≈_ _⊔_ _⊓_
isFiniteHeightLattice = record
{ isLattice = isLattice
; fixedHeight = fixedHeight
}
finiteHeightLattice : FiniteHeightLattice
finiteHeightLattice = record
{ height = 0
; _≈_ = _≈_
; _⊔_ = _⊔_
; _⊓_ = _⊓_
; isFiniteHeightLattice = isFiniteHeightLattice
}
finiteHeightLattice : FiniteHeightLattice
finiteHeightLattice = record
{ height = 0
; _≈_ = _≈_
; _⊔_ = _⊔_
; _⊓_ = _⊓_
; isFiniteHeightLattice = isFiniteHeightLattice
}

11
Main.agda
View File

@@ -1,11 +1,13 @@
{-# OPTIONS --guardedness #-}
module Main where
open import Language
open import Analysis.Sign
open import Language hiding (_++_)
open import Data.Vec using (Vec; _∷_; [])
open import IO
open import Level using (0)
open import Data.String using (_++_)
import Analysis.Constant as ConstantAnalysis
import Analysis.Sign as SignAnalysis
testCode : Stmt
testCode =
@@ -38,6 +40,7 @@ testProgram = record
{ rootStmt = testCode
}
open WithProg testProgram using (output; analyze-correct)
open SignAnalysis.WithProg testProgram using (analyze-correct) renaming (output to output-Sign)
open ConstantAnalysis.WithProg testProgram using (analyze-correct) renaming (output to output-Const)
main = run {0} (putStrLn output)
main = run {0} (putStrLn (output-Const ++ "\n" ++ output-Sign))

79
Utils.agda
View File

@@ -1,19 +1,31 @@
module Utils where
open import Agda.Primitive using () renaming (_⊔_ to _⊔_)
open import Data.Product as Prod using (_×_)
open import Data.Product as Prod using (Σ; _×_; _,_; proj₁; proj₂)
open import Data.Nat using (; suc)
open import Data.Fin as Fin using (Fin; suc; zero)
open import Data.Fin.Properties using (suc-injective)
open import Data.List using (List; cartesianProduct; []; _∷_; _++_; foldr; filter) renaming (map to mapˡ)
open import Data.List.Membership.Propositional using (_∈_)
open import Data.List.Membership.Propositional using (_∈_; lose)
open import Data.List.Membership.Propositional.Properties as ListMemProp using ()
open import Data.List.Relation.Unary.All using (All; []; _∷_; map)
open import Data.List.Relation.Unary.Any using (Any; here; there) -- TODO: re-export these with nicer names from map
open import Data.List.Relation.Unary.All using (All; []; _∷_; map; all?; lookup)
open import Data.List.Relation.Unary.All.Properties using (++⁻ˡ; ++⁻ʳ)
open import Data.List.Relation.Unary.Any as Any using (Any; here; there; any?) -- TODO: re-export these with nicer names from map
open import Data.Sum using (_⊎_)
open import Function.Definitions using (Injective)
open import Relation.Binary using (Antisymmetric) renaming (Decidable to Decidable²)
open import Relation.Binary.PropositionalEquality using (_≡_; sym; refl; cong)
open import Relation.Nullary using (¬_; yes; no)
open import Relation.Nullary using (¬_; yes; no; Dec)
open import Relation.Nullary.Decidable using (¬?)
open import Relation.Unary using (Decidable)
All¬-¬Any : {p c} {C : Set c} {P : C Set p} {l : List C} All (λ x ¬ P x) l ¬ Any P l
All¬-¬Any {l = x xs} (¬Px _) (here Px) = ¬Px Px
All¬-¬Any {l = x xs} (_ ¬Pxs) (there Pxs) = All¬-¬Any ¬Pxs Pxs
Decidable-¬ : {p c} {C : Set c} {P : C Set p} Decidable P Decidable (λ x ¬ P x)
Decidable-¬ Decidable-P x = ¬? (Decidable-P x)
data Unique {c} {C : Set c} : List C Set c where
empty : Unique []
push : {x : C} {xs : List C}
@@ -34,6 +46,24 @@ Unique-append {c} {C} {x} {x' ∷ xs'} x∉xs (push x'≢ uxs') =
help {[]} _ = x'≢x []
help {e es} (x'≢e x'≢es) = x'≢e help x'≢es
Unique-++⁻ˡ : {c} {C : Set c} (xs : List C) {ys : List C} Unique (xs ++ ys) Unique xs
Unique-++⁻ˡ [] Unique-ys = empty
Unique-++⁻ˡ (x xs) {ys} (push x≢xs++ys Unique-xs++ys) = push (++⁻ˡ xs {ys = ys} x≢xs++ys) (Unique-++⁻ˡ xs Unique-xs++ys)
Unique-++⁻ʳ : {c} {C : Set c} (xs : List C) {ys : List C} Unique (xs ++ ys) Unique ys
Unique-++⁻ʳ [] Unique-ys = Unique-ys
Unique-++⁻ʳ (x xs) {ys} (push x≢xs++ys Unique-xs++ys) = Unique-++⁻ʳ xs Unique-xs++ys
Unique-∈-++ˡ : {c} {C : Set c} {x : C} (xs : List C) {ys : List C} Unique (xs ++ ys) x xs ¬ x ys
Unique-∈-++ˡ [] _ ()
Unique-∈-++ˡ {x = x} (x' xs) (push x≢xs++ys _) (here refl) = All¬-¬Any (++⁻ʳ xs x≢xs++ys)
Unique-∈-++ˡ {x = x} (x' xs) (push _ Unique-xs++ys) (there x̷∈xs) = Unique-∈-++ˡ xs Unique-xs++ys x̷∈xs
Unique-narrow : {c} {C : Set c} {x : C} (xs : List C) {ys : List C} Unique (xs ++ ys) x xs Unique (x ys)
Unique-narrow [] _ ()
Unique-narrow {x = x} (x' xs) (push x≢xs++ys Unique-xs++ys) (here refl) = push (++⁻ʳ xs x≢xs++ys) (Unique-++⁻ʳ xs Unique-xs++ys)
Unique-narrow {x = x} (x' xs) (push _ Unique-xs++ys) (there x̷∈xs) = Unique-narrow xs Unique-xs++ys x̷∈xs
All-≢-map : {c d} {C : Set c} {D : Set d} (x : C) {xs : List C} (f : C D)
Injective (_≡_ {_} {C}) (_≡_ {_} {D}) f
All (λ x' ¬ x x') xs All (λ y' ¬ (f x) y') (mapˡ f xs)
@@ -46,9 +76,8 @@ Unique-map : ∀ {c d} {C : Set c} {D : Set d} {l : List C} (f : C → D) →
Unique-map {l = []} _ _ _ = empty
Unique-map {l = x xs} f f-Injecitve (push x≢xs uxs) = push (All-≢-map x f f-Injecitve x≢xs) (Unique-map f f-Injecitve uxs)
All¬-¬Any : {p c} {C : Set c} {P : C Set p} {l : List C} All (λ x ¬ P x) l ¬ Any P l
All¬-¬Any {l = x xs} (¬Px _) (here Px) = ¬Px Px
All¬-¬Any {l = x xs} (_ ¬Pxs) (there Pxs) = All¬-¬Any ¬Pxs Pxs
¬Any-map : {p p₂ c} {C : Set c} {P : C Set p} {P₂ : C Set p₂} {l : List C} ( {x} P₁ x P x) ¬ Any P₂ l ¬ Any P l
¬Any-map f ¬Any-P₂ Any-P₁ = ¬Any-P₂ (Any.map f Any-P₁)
All-single : {p c} {C : Set c} {P : C Set p} {c : C} {l : List C} All P l c l P c
All-single {c = c} {l = x xs} (p ps) (here refl) = p
@@ -103,3 +132,37 @@ __ P Q a = P a ⊎ Q a
_∧_ : {a p₁ p₂} {A : Set a} (P : A Set p₁) (Q : A Set p₂)
A Set (p₁ ⊔ℓ p₂)
_∧_ P Q a = P a × Q a
it : {a} {A : Set a} {{_ : A}} A
it {{x}} = x
z≢sf : {n : } (f : Fin n) ¬ (Fin.zero Fin.suc f)
z≢sf f ()
z≢mapsfs : {n : } (fs : List (Fin n)) All (λ sf ¬ zero sf) (mapˡ suc fs)
z≢mapsfs [] = []
z≢mapsfs (f fs') = z≢sf f z≢mapsfs fs'
fins : (n : ) Σ (List (Fin n)) Unique
fins 0 = ([] , empty)
fins (suc n') =
let
(inds' , unids') = fins n'
in
( zero mapˡ suc inds'
, push (z≢mapsfs inds') (Unique-map suc suc-injective unids')
)
fins-complete : (n : ) (f : Fin n) f (proj₁ (fins n))
fins-complete (suc n') zero = here refl
fins-complete (suc n') (suc f') = there (x∈xs⇒fx∈fxs suc (fins-complete n' f'))
findUniversal : {p c} {C : Set c} {R : C C Set p} (l : List C) Decidable² R
Dec (Any (λ x All (R x) l) l)
findUniversal l Rdec = any? (λ x all? (Rdec x) l) l
findUniversal-unique : {p c} {C : Set c} (R : C C Set p) (l : List C)
Antisymmetric _≡_ R
x₁ x₂ x₁ l x₂ l All (R x₁) l All (R x₂) l
x₁ x₂
findUniversal-unique R l Rantisym x₁ x₂ x₁∈l x₂∈l Allx₁ Allx₂ = Rantisym (lookup Allx₁ x₂∈l) (lookup Allx₂ x₁∈l)