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PrimitiveSpec.hs
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PrimitiveSpec.hs
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{-# LANGUAGE DataKinds #-}
{-# LANGUAGE FlexibleInstances #-}
{-# OPTIONS_GHC -fno-warn-orphans #-}
module Cardano.Wallet.PrimitiveSpec
( spec
) where
import Prelude
import Cardano.Wallet.Primitive
( Address (..)
, Block (..)
, BlockHeader (..)
, Coin (..)
, Dom (..)
, EpochId (..)
, Hash (..)
, SlotId (..)
, Tx (..)
, TxIn (..)
, TxOut (..)
, UTxO (..)
, balance
, excluding
, isSubsetOf
, isValidCoin
, restrictedBy
, restrictedTo
, updatePending
)
import Data.Set
( Set, (\\) )
import Test.Hspec
( Spec, describe, it )
import Test.QuickCheck
( Arbitrary (..)
, Property
, checkCoverage
, choose
, cover
, oneof
, property
, scale
, vectorOf
, (===)
)
import qualified Data.Map.Strict as Map
import qualified Data.Set as Set
spec :: Spec
spec = do
describe "Generators are valid" $ do
it "Arbitrary Coin" $ property isValidCoin
describe "Lemma 2.1 - Properties of UTxO operations" $ do
it "2.1.1) ins⊲ u ⊆ u"
(checkCoverage prop_2_1_1)
it "2.1.2) ins⋪ u ⊆ u"
(checkCoverage prop_2_1_2)
it "2.1.3) u ⊳ outs ⊆ u"
(checkCoverage prop_2_1_3)
it "2.1.4) ins⊲ (u ⋃ v) = (ins⊲ u) ⋃ (ins⊲ v)"
(checkCoverage prop_2_1_4)
it "2.1.5) ins⋪ (u ⋃ v) = (ins⋪ u) ⋃ (ins⋪ v)"
(checkCoverage prop_2_1_5)
it "2.1.6) (dom u ⋂ ins) ⊲ u = ins⊲ u"
(checkCoverage prop_2_1_6)
it "2.1.7) (dom u ⋂ ins) ⋪ u = ins⋪ u"
(checkCoverage prop_2_1_7)
it "2.1.8) (dom u ⋃ ins) ⋪ (u ⋃ v) = (ins ⋃ dom u) ⋪ v"
(checkCoverage prop_2_1_8)
it "2.1.9) ins⋪ u = (dom u \\ ins)⊲ u"
(checkCoverage prop_2_1_9)
describe "Lemma 2.6 - Properties of balance" $ do
it "2.6.1) dom u ⋂ dom v ==> balance (u ⋃ v) = balance u + balance v"
(checkCoverage prop_2_6_1)
it "2.6.2) balance (ins⋪ u) = balance u - balance (ins⊲ u)"
(checkCoverage prop_2_6_2)
describe "Lemma 3.3 - Updating the pending set" $ do
it "3.3) updatePending b pending ⊆ pending"
(checkCoverage prop_3_2)
{-------------------------------------------------------------------------------
Wallet Specification - Lemma 2.1 - Properties of UTxO operations
-------------------------------------------------------------------------------}
prop_2_1_1 :: (Set TxIn, UTxO) -> Property
prop_2_1_1 (ins, u) =
cover 50 cond "dom u ⋂ ins ≠ ∅" (property prop)
where
cond = not $ Set.null $ dom u `Set.intersection` ins
prop = (u `restrictedBy` ins) `isSubsetOf` u
prop_2_1_2 :: (Set TxIn, UTxO) -> Property
prop_2_1_2 (ins, u) =
cover 50 cond "dom u ⋂ ins ≠ ∅" (property prop)
where
cond = not $ Set.null $ dom u `Set.intersection` ins
prop = (u `excluding` ins) `isSubsetOf` u
prop_2_1_3 :: (Set TxOut, UTxO) -> Property
prop_2_1_3 (outs, u) =
cover 50 cond "u ⋂ outs ≠ ∅" (property prop)
where
cond = not $ Set.null $
Set.fromList (Map.elems (getUTxO u)) `Set.intersection` outs
prop = (u `restrictedTo` outs) `isSubsetOf` u
prop_2_1_4 :: (Set TxIn, UTxO, UTxO) -> Property
prop_2_1_4 (ins, u, v) =
cover 50 cond "(dom u ⋃ dom v) ⋂ ins ≠ ∅" (property prop)
where
cond = not $ Set.null $ Set.union (dom u) (dom v) `Set.intersection` ins
prop =
((u <> v) `restrictedBy` ins)
===
(u `restrictedBy` ins) <> (v `restrictedBy` ins)
prop_2_1_5 :: (Set TxIn, UTxO, UTxO) -> Property
prop_2_1_5 (ins, u, v) =
cover 50 cond "(dom u ⋃ dom v) ⋂ ins ≠ ∅" (property prop)
where
cond = not $ Set.null $ Set.union (dom u) (dom v) `Set.intersection` ins
prop =
((u <> v) `excluding` ins)
===
(u `excluding` ins) <> (v `excluding` ins)
prop_2_1_6 :: (Set TxIn, UTxO) -> Property
prop_2_1_6 (ins, u) =
cover 50 cond "dom u ⋂ ins ≠ ∅" (property prop)
where
cond = not $ Set.null $ dom u `Set.intersection` ins
prop =
(u `restrictedBy` (dom u `Set.intersection` ins))
===
(u `restrictedBy` ins)
prop_2_1_7 :: (Set TxIn, UTxO) -> Property
prop_2_1_7 (ins, u) =
cover 50 cond "dom u ⋂ ins ≠ ∅" (property prop)
where
cond = not $ Set.null $ dom u `Set.intersection` ins
prop =
(u `excluding` (dom u `Set.intersection` ins))
===
(u `excluding` ins)
prop_2_1_8 :: (Set TxIn, UTxO, UTxO) -> Property
prop_2_1_8 (ins, u, v) =
cover 50 cond "dom u ⋂ ins ≠ ∅" (property prop)
where
cond = not $ Set.null $ dom u `Set.intersection` ins
prop =
((u <> v) `excluding` (dom u <> ins))
===
v `excluding` (ins <> dom u)
prop_2_1_9 :: (Set TxIn, UTxO) -> Property
prop_2_1_9 (ins, u) =
cover 50 cond "dom u ⋂ ins ≠ ∅" (property prop)
where
cond = not $ Set.null $ dom u `Set.intersection` ins
prop = (u `excluding` ins) === u `restrictedBy` (dom u \\ ins)
{-------------------------------------------------------------------------------
Wallet Specification - Lemma 2.6 - Properties of Balance
-------------------------------------------------------------------------------}
prop_2_6_1 :: (UTxO, UTxO) -> Property
prop_2_6_1 (u, v) =
cover 50 cond "u ≠ ∅ , v ≠ ∅" (property prop)
where
-- NOTE:
-- A precondition (u ⋂ v = ∅ ) is hard to satisfy because our generators
-- are built in order to not be 'too entropic'. So, we better just create
-- a v' that has no overlap with u.
v' = v `excluding` dom u
cond = not (u `isSubsetOf` mempty || v' `isSubsetOf` mempty)
prop = balance (u <> v') === balance u + balance v'
prop_2_6_2 :: (Set TxIn, UTxO) -> Property
prop_2_6_2 (ins, u) =
cover 50 cond "dom u ⋂ ins ≠ ∅" (property prop)
where
cond = not $ Set.null $ dom u `Set.intersection` ins
prop =
balance (u `excluding` ins)
===
balance u - balance (u `restrictedBy` ins)
{-------------------------------------------------------------------------------
Wallet Specification - Lemma 3.3 - Update the Pending Set
-------------------------------------------------------------------------------}
prop_3_2 :: (Block, Set Tx) -> Property
prop_3_2 (b, pending) =
cover 50 cond0 "pending ≠ ∅ " $
cover 10 cond1 "transactions b ⋂ pending ≠ ∅ " $
property prop
where
cond0 = not $ Set.null pending
cond1 = not $ Set.null $ transactions b `Set.intersection` pending
prop = updatePending b pending `Set.isSubsetOf` pending
{-------------------------------------------------------------------------------
Arbitrary Instances
Arbitrary instances define here aren't necessarily reflecting on real-life
scenario, but they help test the property above by constructing data
structures that don't have much entropy and therefore, allow us to even test
something when checking for intersections and set restrictions!
-------------------------------------------------------------------------------}
instance Arbitrary (Hash "Tx") where
-- No Shrinking
arbitrary = oneof
[ pure $ Hash "TXID01"
, pure $ Hash "TXID02"
, pure $ Hash "TXID03"
]
-- Same for addresses
instance Arbitrary Address where
-- No Shrinking
arbitrary = oneof
[ pure $ Address "ADDR01"
, pure $ Address "ADDR02"
, pure $ Address "ADDR03"
]
instance Arbitrary Coin where
-- No Shrinking
arbitrary = Coin <$> choose (0, 3)
instance Arbitrary EpochId where
arbitrary = EpochId <$> arbitrary
instance Arbitrary SlotId where
arbitrary = SlotId <$> arbitrary
instance Arbitrary TxOut where
-- No Shrinking
arbitrary = TxOut
<$> arbitrary
<*> arbitrary
instance Arbitrary TxIn where
-- No Shrinking
arbitrary = TxIn
<$> arbitrary
<*> scale (`mod` 3) arbitrary -- No need for a crazy high indexes
instance Arbitrary UTxO where
shrink (UTxO utxo) = UTxO <$> shrink utxo
arbitrary = do
n <- choose (0, 10)
utxo <- zip
<$> vectorOf n arbitrary
<*> vectorOf n arbitrary
return $ UTxO $ Map.fromList utxo
instance Arbitrary Tx where
shrink (Tx ins outs) =
(flip Tx outs <$> shrink ins) <> (Tx ins <$> shrink outs)
arbitrary = do
ins <- choose (1, 3) >>= flip vectorOf arbitrary
outs <- choose (1, 3) >>= flip vectorOf arbitrary
return $ Tx ins outs
instance Arbitrary BlockHeader where
-- No Shrinking
arbitrary = BlockHeader
<$> arbitrary
<*> arbitrary
<*> oneof
[ pure $ Hash "BLOCK01"
, pure $ Hash "BLOCK02"
, pure $ Hash "BLOCK03"
]
instance Arbitrary Block where
shrink (Block h txs) = Block h <$> shrink txs
arbitrary = do
txs <- choose (0, 500) >>= flip vectorOf arbitrary
Block <$> arbitrary <*> pure (Set.fromList txs)