程序代写代做代考 cache C Copies: Reference vs. Shallow vs. Deep Writing Complete Postconditions

Copies: Reference vs. Shallow vs. Deep Writing Complete Postconditions
EECS3311 A: Software Design Winter 2020
CHEN-WEI WANG

Copying Objects
Say variables c1 and c2 are both declared of type C. [ c1, c2: C ] ● There is only one attribute a declared in class C.
● c1.a and c2.a are references to objects.
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c1
c1.a
C
a
c2
a
C
c2.a

Copying Objects: Reference Copy
Reference Copy
○ Copy the address stored in variable c2 and store it in c1.
⇒ Both c1 and c2 point to the same object.
⇒ Updates performed via c1 also visible to c2. [ aliasing ]
c1 := c2
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c1
c1.a
C
a
c2
a
C
c2.a

Copying Objects: Shallow Copy
Shallow Copy
○ Create a temporary, behind-the-scene object c3 of type C.
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○ Initialize each attribute a of c3 via reference copy: ○ Make a reference copy of c3:
c3.a := c2.a c1 := c3 [ c1 /= c2 ]
⇒ c1 and c2 are not pointing to the same object.
⇒ c1.a and c2.a are pointing to the same object.
⇒ Aliasing still occurs: at 1st level (i.e., attributes of c1 and c2)
a
C
c1 := c2.twin
c1
c3
c2
c2.a
c1.a
a
C
a
C

Copying Objects: Deep Copy
Deep Copy
○ Create a temporary, behind-the-scene object c3 of type C. ○ Recursively initialize each attribute a of c3 as follows:
c1 := c2.deep_twin
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Base Case: a is primitive (e.g., INTEGER).  c3.a := c2.a. Recursive Case: a is referenced.  c3.a := c2.a.deep_twin
○ Make a reference copy of c3:
⇒ c1 and c2 are not pointing to the same object.
⇒ c1.a and c2.a are not pointing to the same object. ⇒ No aliasing occurs at any levels.
c1 := c3
c1
c3
C a
a
c1.a
c2.a.deep_twin
c2.a
C
C
c2
a

Copying OShbajelclotsw and deep cloning
a
O1
! Initial situation: ! Result of:
name landlord loved_one
O2
“Almaviva”
O3
“Figaro”
“Susanna”
b := a
b
c := a.twin
O4 c
“Almaviva”
d := a.deep_twin
O6
d name landlord loved_one
“Almaviva”
O5
“Figaro”
O7
“Susanna”
EE6CSo,fYo3r9kUniversity ObjectOrientedSoftwareConstruction 15-05-2716:29 28

Example: Collection Objects (1)
○ In any OOPL, when a variable is declared of a type that corresponds to a known class (e.g., STRING, ARRAY, LINKED LIST, etc.):
At runtime, that variable stores the address of an object of that type (as opposed to storing the object in its entirety).
○ Assume the following variables of the same type:
local
imp : ARRAY[STRING] old_imp: ARRAY[STRING]
do
create {ARRAY[STRING]} imp.make_empty imp.force(“Alan”, 1) imp.force(“Mark”, 2)
imp.force(“Tom”, 3)
Before we undergo a change on imp, we “ copy ” it to old imp. After the change is completed, we compare imp vs. old imp. Can a change always be visible between “old” and “new” imp?
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Example: Collection Objects (2)
● Variables imp and old imp store address(es) of some array(s). ● Each “slot” of these arrays stores a STRING object’s address.
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imp
imp[1] imp[2] imp[3]
STRING
value
“Mark”
STRING
value
“Alan”
old_imp
ARRAY[STRING]
??
STRING
value
“Tom”

Reference Copy of Collection Object
1 2
3 4 5 6 7
old imp := imp
Result := old_imp = imp — Result = true imp[2] := “Jim”
Result :=
across 1 |..| imp.count is j all imp [j]  old_imp [j] end — Result = true
Before Executing L3
After Executing L3
ARRAY[STRING]
old_imp
imp
ARRAY[STRING]
old_imp
imp
STRING
value
“Alan”
“Mark” “Tom”
STRING
value
STRING
value
STRING
STRING
STRING
STRING
value
“Alan”
value
“Mark”
value
“Tom”
value
“Jim”
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1 2
3 4 5 6 7
Shallow Copy of Collection Object (1)
old imp := imp.twin
Result := old_imp = imp — Result = false imp[2] := “Jim”
Result :=
across 1 |..| imp.count is j all imp [j]  old_imp [j] end — Result = false
Before Executing L3
After Executing L3
ARRAY[STRING]
ARRAY[STRING]
STRING
imp
old_imp
imp
old_imp
value
“Jim”
STRING
STRING
STRING
STRING
STRING
value
“Alan”
value
“Mark”
STRING
value
“Tom”
value
“Alan”
value
“Mark”
ARRA
Y[STR
ING]
ARRA
Y[STR
ING]
value
“Tom”
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1 2
3 4 5 6 7
Shallow Copy of Collection Object (2)
old imp := imp.twin
Result := old_imp = imp — Result = false imp[2].append (“***”)
Result :=
across 1 |..| imp.count is j all imp [j]  old_imp [j] end — Result = true
Before Executing L3
After Executing L3
ARRAY[STRING]
ARRAY[STRING]
imp
old_imp
imp
old_imp
“Mark***”
STRING
STRING
STRING
STRING
STRING
value
“Alan”
value
“Mark”
value
“Tom”
value
“Alan”
value
“Mark”
STRING
value
ARRA
Y[STR
ING]
ARRA
Y[STR
ING]
“Tom”
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1 2
3 4 5 6
Deep Copy of Collection Object (1)
old imp := imp.deep twin
Result := old_imp = imp — Result = false imp[2] := “Jim”
Result :=
across 1 |..| imp.count is j
all imp [j]  old_imp [j] end — Result = false
Before Executing L3
After Executing L3
imp
ARRAY[STRING]
STRING STRING STRING value “Alan” value “Mark” value “Tom”
STRING STRING STRING value “Alan” value “Mark” value “Tom”
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imp
STRING
ARRAY[STRING]
ING
ST
“Jim”
STRING
STRING
value
“Alan”
value
STRING
STRING
value
“Alan”
“Mark”
“Mark”
“Tom”
value
R value
value
“Tom”
STRING
value
old_imp
old_imp
ARRAY[STRING]
ARRAY[STRING]

Deep Copy of Collection Object (2)
1 2
3 4 5 6
old imp := imp.deep twin
Result := old_imp = imp — Result = false imp[2].append (“***”)
Result :=
across 1 |..| imp.count is j
all imp [j]  old_imp [j] end — Result = false
imp
ARRAY[STRING]
STRING STRING STRING value “Alan” value “Mark” value “Tom”
STRING STRING STRING value “Alan” value “Mark” value “Tom”
old_imp
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Before Executing L3
After Executing L3
imp
ARRAY[STRING]
STRING STRING STRING value “Alan” value “Mark” value “Tom”
“Mark***”
old_imp
STRING STRING STRING value “Alan” value “Mark” value “Tom”
ARRAY[STRING]
ARRAY[STRING]

How are contracts checked at runtime?
○ All contracts are specified as Boolean expressions.
○ Right before a feature call (e.g., acc.withdraw(10)):
The current state of acc is called its pre-state.
Evaluate pre-condition using current values of attributes/queries.
Cache values, via e.g.,
e.g.,
e.g.,
e.g., e.g., e.g., e.g.,
, of old expressions in the post-condition .
[ old accounts i id ∶= accounts[i].id ] [ old accounts i ∶= accounts[i] ] [ old accounts i twin ∶= accounts[i].twin ] [ old accounts ∶= accounts ] [ old accounts twin ∶= accounts.twin ] [ old current ∶= Current ] [ old current twin ∶= Current.twin ]
:=
old accounts[i].id
(old accounts[i]).id
(old accounts[i].twin).id
(old accounts)[i].id
(old accounts.twin)[i].id
(old Current).accounts[i].id
(old Current.twin).accounts[i].id
○ Right after the feature call:
The current state of acc is called its post-state.
Evaluate invariant using current values of attributes and queries. Evaluate post-condition using both current values and “cached” values of attributes and queries.
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When are contracts complete?
● In post-condition , for each attribute , specify the relationship between its pre-state value and its post-state value.
○ Eiffel supports this purpose using the old keyword.
● This is tricky for attributes whose structures are composite rather than simple:
e.g., ARRAY, LINKED LIST are composite-structured. e.g., INTEGER, BOOLEAN are simple-structured.
● Rule of thumb: For an attribute whose structure is composite, we should specify that after the update:
1. The intended change is present; and
2. The rest of the structure is unchanged .
● The second contract is much harder to specify:
○ Reference aliasing [ ref copy vs. shallow copy vs. deep copy ] ○ Iterable structure [ use across ]
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Account
class
ACCOUNT
inherit ANY
redefine is_equal end create
make
feature — Attributes owner: STRING balance: INTEGER
feature — Commands make (n: STRING)
do
owner := n
balance := 0 end
deposit(a: INTEGER) do
balance := balance + a ensure
balance = old balance + a end
is_equal(other: ACCOUNT): BOOLEAN do
Result :=
owner  other.owner
and balance = other.balance end
end
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Bank
class BANK create make feature
accounts: ARRAY[ACCOUNT]
make do create accounts.make_empty end account_of (n: STRING): ACCOUNT
require — the input name exists
existing: across accounts is acc some acc.owner  n end
— not (across accounts is acc all acc.owner / n end) do … ensure Result.owner  n end
add (n: STRING)
require — the input name does not exist
non_existing: across accounts is acc all acc.owner / n end — not (across accounts is acc some acc.owner  n end)
local new_account: ACCOUNT do
create new_account.make (n)
accounts.force (new_account, accounts.upper + 1) end
end
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Roadmap of Illustrations
We examine 5 different versions of a command
deposit on (n ∶ STRING; a ∶ INTEGER)
VERSION
1 2 3 4 5
IMPLEMENTATION
Correct
Wrong Wrong Wrong Wrong
CONTRACTS
SATISFACTORY?
Incomplete No
Incomplete No Complete (reference copy) No Complete (shallow copy) No
Complete (deep copy) Yes
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Object Structure for Illustration
We will test each version by starting with the same runtime object structure:
BANK accounts
b.accounts
01
b
ACCOUNT
owner
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balance
0
ACCOUNT
owner
“Bill” “Steve”
balance
0

Version 1:
Incomplete Contracts, Correct Implementation
class BANK
deposit_on_v1 (n: STRING; a: INTEGER)
require across accounts is acc some acc.owner  n end local i: INTEGER
do
from i := accounts.lower until i > accounts.upper loop
if accounts[i].owner  n then accounts[i].deposit(a) end
i := i + 1 end
ensure
num_of_accounts_unchanged: accounts.count = old accounts.count
balance_of_n_increased: Current.account_of(n).balance =
old Current.account_of(n).balance + a end
end
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Test of Version 1
class TEST_BANK test_bank_deposit_correct_imp_incomplete_contract: BOOLEAN
local
b: BANK do
comment(“t1: correct imp and incomplete contract”) create b.make
b.add (“Bill”)
b.add (“Steve”)
— deposit 100 dollars to Steve’s account
b.deposit on v1 (“Steve”, 100)
Result := b.account_of(“Bill”).balance = 0
and b.account_of(“Steve”).balance = 100 check Result end
end end
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Test of Version 1: Result
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Version 2:
Incomplete Contracts, Wrong Implementation
class BANK
deposit_on_v2 (n: STRING; a: INTEGER)
require across accounts is acc some acc.owner  n end local i: INTEGER
do …
— imp. of version 1, followed by a deposit into 1st account
accounts[accounts.lower].deposit(a)
ensure
num_of_accounts_unchanged: accounts.count = old accounts.count
balance_of_n_increased: Current.account_of(n).balance =
old Current.account_of(n).balance + a end
end
Current postconditions lack a check that accounts other than n
are unchanged.
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Test of Version 2
class TEST_BANK test_bank_deposit_wrong_imp_incomplete_contract: BOOLEAN
local
b: BANK do
comment(“t2: wrong imp and incomplete contract”) create b.make
b.add (“Bill”)
b.add (“Steve”)
— deposit 100 dollars to Steve’s account
b.deposit on v2 (“Steve”, 100)
Result := b.account_of(“Bill”).balance = 0
and b.account_of(“Steve”).balance = 100 check Result end
end end
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Test of Version 2: Result
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Version 3:
Complete Contracts with Reference Copy
class BANK
deposit_on_v3 (n: STRING; a: INTEGER)
require across accounts is acc some acc.owner  n end local i: INTEGER
do …
— imp. of version 1, followed by a deposit into 1st account
accounts[accounts.lower].deposit(a)
ensure
num_of_accounts_unchanged: accounts.count = old accounts.count balance_of_n_increased:
Current.account_of(n).balance =
old Current.account_of(n).balance + a
others unchanged :
across old accounts is acc all
acc.owner / n implies acc  Current.account_of(acc.owner) end
end end
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Test of Version 3
class TEST_BANK test_bank_deposit_wrong_imp_complete_contract_ref_copy: BOOLEAN
local
b: BANK do
comment(“t3: wrong imp and complete contract with ref copy”) create b.make
b.add (“Bill”)
b.add (“Steve”)
— deposit 100 dollars to Steve’s account
b.deposit on v3 (“Steve”, 100)
Result := b.account_of(“Bill”).balance = 0
and b.account_of(“Steve”).balance = 100 check Result end
end end
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Test of Version 3: Result
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Version 4:
Complete Contracts with Shallow Object Copy
class BANK
deposit_on_v4 (n: STRING; a: INTEGER)
require across accounts is acc some acc.owner  n end local i: INTEGER
do …
— imp. of version 1, followed by a deposit into 1st account
accounts[accounts.lower].deposit(a)
ensure
num_of_accounts_unchanged: accounts.count = old accounts.count balance_of_n_increased:
Current.account_of(n).balance =
old Current.account_of(n).balance + a
others unchanged :
across old accounts.twin is acc all
acc.owner / n implies acc  Current.account_of(acc.owner) end
end end
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Test of Version 4
class TEST_BANK test_bank_deposit_wrong_imp_complete_contract_shallow_copy: BOOLEAN
local
b: BANK do
comment(“t4: wrong imp and complete contract with shallow copy”) create b.make
b.add (“Bill”)
b.add (“Steve”)
— deposit 100 dollars to Steve’s account
b.deposit on v4 (“Steve”, 100)
Result := b.account_of(“Bill”).balance = 0
and b.account_of(“Steve”).balance = 100 check Result end
end end
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Test of Version 4: Result
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Version 5:
Complete Contracts with Deep Object Copy
class BANK
deposit_on_v5 (n: STRING; a: INTEGER)
require across accounts is acc some acc.owner  n end local i: INTEGER
do …
— imp. of version 1, followed by a deposit into 1st account accounts[accounts.lower].deposit(a)
ensure
num_of_accounts_unchanged: accounts.count = old accounts.count balance_of_n_increased:
Current.account_of(n).balance =
old Current.account_of(n).balance + a
others unchanged :
across old accounts.deep twin is acc all
acc.owner / n implies acc  Current.account_of(acc.owner) end
end end
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Test of Version 5
class TEST_BANK test_bank_deposit_wrong_imp_complete_contract_deep_copy: BOOLEAN
local
b: BANK do
comment(“t5: wrong imp and complete contract with deep copy”) create b.make
b.add (“Bill”)
b.add (“Steve”)
— deposit 100 dollars to Steve’s account
b.deposit on v5 (“Steve”, 100)
Result := b.account_of(“Bill”).balance = 0
and b.account_of(“Steve”).balance = 100 check Result end
end end
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Test of Version 5: Result
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Exercise
● Consider the query account of (n: STRING) of BANK.
● How do we specify (part of) its postcondition to assert that the
state of the bank remains unchanged:
○ [×] ○ [×] ○ [×] ○ [×] ○ [×] ○ [✓]
● Which equality of the above is appropriate for the postcondition?
● Why is each one of the other equalities not appropriate? 35 of 39
accounts = old accounts
accounts = old accounts.twin
accounts = old accounts.deep_twin
accounts ̃ old accounts
accounts ̃ old accounts.twin
accounts ̃ old accounts.deep_twin

Index (1)
Copying Objects
Copying Objects: Reference Copy Copying Objects: Shallow Copy Copying Objects: Deep Copy Example: Copying Objects
Example: Collection Objects (1) Example: Collection Objects (2) Reference Copy of Collection Object Shallow Copy of Collection Object (1) Shallow Copy of Collection Object (2)
Deep Copy of Collection Object (1)
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Index (2)
Deep Copy of Collection Object (2)
How are contracts checked at runtime?
When are contracts complete?
Account
Bank
Roadmap of Illustrations
Object Structure for Illustration
Version 1:
Incomplete Contracts, Correct Implementation
Test of Version 1
Test of Version 1: Result
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Index (3) Version 2:
Incomplete Contracts, Wrong Implementation Test of Version 2
Test of Version 2: Result
Version 3:
Complete Contracts with Reference Copy
Test of Version 3
Test of Version 3: Result
Version 4:
Complete Contracts with Shallow Object Copy
Test of Version 4
Test of Version 4: Result
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Index (4)
Version 5:
Complete Contracts with Deep Object Copy
Test of Version 5
Test of Version 5: Result Exercise
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