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Iris
Actris
Commits
1130d468
Commit
1130d468
authored
May 06, 2020
by
Jonas Kastberg
Browse files
Merge branch 'daniel/headers' into 'master'
File headers See merge request
!16
parents
ee0d1bfc
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#27751
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63
theories/channel/channel.v
theories/channel/channel.v
+4
1
theories/channel/proto.v
theories/channel/proto.v
+31
27
theories/logrel/environments.v
theories/logrel/environments.v
+13
1
theories/logrel/examples/double.v
theories/logrel/examples/double.v
+11
0
theories/logrel/examples/pair.v
theories/logrel/examples/pair.v
+9
0
theories/logrel/kind_tele.v
theories/logrel/kind_tele.v
+2
0
theories/logrel/lib/mutex.v
theories/logrel/lib/mutex.v
+26
0
theories/logrel/model.v
theories/logrel/model.v
+14
0
theories/logrel/operators.v
theories/logrel/operators.v
+3
1
theories/logrel/session_types.v
theories/logrel/session_types.v
+4
0
theories/logrel/subtyping.v
theories/logrel/subtyping.v
+16
1
theories/logrel/subtyping_rules.v
theories/logrel/subtyping_rules.v
+4
2
theories/logrel/term_types.v
theories/logrel/term_types.v
+44
19
theories/logrel/term_typing_judgment.v
theories/logrel/term_typing_judgment.v
+8
0
theories/logrel/term_typing_rules.v
theories/logrel/term_typing_rules.v
+14
11
No files found.
theories/channel/channel.v
View file @
1130d468
...
...
@@ 17,7 +17,10 @@ In this file we define the three messagepassing connectives:
polarity of the endpoints.
 [send] takes an endpoint and adds an element to the first buffer.
 [recv] performs a busy loop until there is something in the second buffer,
which it pops and returns, locking during each peek.*)
which it pops and returns, locking during each peek.
It is additionaly shown that the channel ownership [c ↣ prot] is closed under
the subprotocol relation [⊑] *)
From
iris
.
heap_lang
Require
Export
lifting
notation
.
From
iris
.
heap_lang
Require
Import
proofmode
.
From
iris
.
heap_lang
.
lib
Require
Import
spin_lock
.
...
...
theories/channel/proto.v
View file @
1130d468
...
...
@@ 2,23 +2,46 @@
separation protocols and the various operations on it like dual, append, and
branching.
Dependent separation protocols are defined by instantiating the parameterized
version in [proto_model] with type of propositions [iProp] of Iris. We define
ways of constructing instances of the instantiated type via two constructors:
Dependent separation protocols [iProto] are defined by instantiating the
parameterized version in [proto_model] with the type of propositions [iProp] of Iris.
We define ways of constructing instances of the instantiated type via two
constructors:
 [iProto_end], which is identical to [proto_end].
 [iProto_message], which takes an action and a continuation to construct
the corresponding message protocols.
 [iProto_message], which takes an [action] and an [iMsg] which is a
sequence of binders [iMsg_exist] terminated by the payload
constructed with [iMsg_base] based on arguments v, P and prot
which are the value, the carried proposition and the [iProto] tail
respectively.
For convenience sake, we provide the following notations:
 [END], which is simply [iProto_end].
 [<!> x1 .. xn, MSG v; {{ P }}; prot] and [<?> x1 .. xn, MSG v; {{ P }}; prot],
which construct an instance of [iProto_message] with the appropriate
continuation.
 [∃ x,m] which is [iMsg_exist] with argument m.
 [MSG v ; {{ P }}; prot] which is [iMsg_Base with
 [<a> m] which is [iProto_message] with arguments a and m.
We also include custom notation to more easily construct complete constructions:
 [<a x1 .. xn> m] which is [<a> ∃ x1, .. ∃ xn, m]
 [<a x1 .. xn> MSG v; {{ P }}; prot], which constructs a full protocol
Futhermore, we define the following operations:
 [iProto_dual], which turns all [Send] of a protocol into [Recv] and viceversa
 [iProto_app], which appends two protocols as described in proto_model.v
In addition we define the subprotocol relation [iProto_le] [⊑], which generalises
the following inductive definition for asynchronous subtyping on session types:
p1 <: p2 p1 <: p2 p1 <: !B.p3 ?A.p3 <: p2
   
end <: end !A.p1 <: !A.p2 ?A.p1 <: ?A.p2 ?A.p1 <: !B.p2
Example:
!R <: !R ?Q <: ?Q ?Q <: ?Q
 
?Q.!R <: !R.?Q ?P.?Q <: ?P.?Q

?P.?Q.!R <: !R.?P.?Q
Lastly, relevant type classes instances are defined for each of the above
notions, such as contractiveness and nonexpansiveness, after which the
specifications of the messagepassing primitives are defined in terms of the
...
...
@@ 210,25 +233,6 @@ Arguments iProto_dual_if {_ _} _ _%proto.
Instance
:
Params
(@
iProto_dual_if
)
3
:
=
{}.
(** * Protocol entailment *)
(* The definition [iProto_le] generalizes the following inductive definition
for subtyping on session types:
p1 <: p2 p1 <: p2
  
end <: end !A.p1 <: !A.p2 ?A.p1 <: ?A.p2
p1 <: !B.p3 ?A.p3 <: p2

?A.p1 <: !B.p2
Example:
!R <: !R ?Q <: ?Q ?Q <: ?Q
 
?Q.!R <: !R.?Q ?P.?Q <: ?P.?Q

?P.?Q.!R <: !R.?P.?Q
*)
Definition
iProto_le_pre
{
Σ
V
}
(
rec
:
iProto
Σ
V
→
iProto
Σ
V
→
iProp
Σ
)
(
p1
p2
:
iProto
Σ
V
)
:
iProp
Σ
:
=
◇
(
p1
≡
END
∗
p2
≡
END
)
∨
...
...
theories/logrel/environments.v
View file @
1130d468
From
actris
.
logrel
Require
Export
term_types
.
(** This file contains definitions related to type environments. The following
relations on environments are defined:
 [env_ltyped Γ vs]: This relation indicates that the value map [vs] contains a
value for each type in the semantic type environment [Γ].
 [env_split Γ Γ1 Γ2]: The semantic type environment [Γ] can be split into
(semantically disjoint) [Γ1] and [Γ2].
 [env_copy Γ Γ']: [Γ'] is a copyable subenvironment of [Γ].
In addition, some lemmas about these definitions are proved, corresponding to
the syntactic typing rules that are typically found in linear/affine type
systems. *)
From
actris
.
logrel
Require
Export
term_types
subtyping
.
From
iris
.
proofmode
Require
Import
tactics
.
Notation
"<![ b := x ]!>"
:
=
...
...
theories/logrel/examples/double.v
View file @
1130d468
(** This file contains a proof that the program
λ c, (recv c  recv c)
can be assigned the semantic type
chan (?int.?int.end) ⊸ (int * int)
This cannot be shown directly using the semantic typing rules, and therefore
manual proof is used to show that the program is semantically welltyped. This
demonstrates the extensibility of the type system. *)
From
iris
.
algebra
Require
Import
frac
auth
excl
updates
.
From
iris
.
heap_lang
.
lib
Require
Export
par
spin_lock
.
From
actris
.
channel
Require
Import
proofmode
.
...
...
theories/logrel/examples/pair.v
View file @
1130d468
(** This file contains shows that the program
λ c, (recv c, recv c)
can be assigned the type
chan (?int.?int.end) ⊸ (int * int)
by exclusively using the semantic typing rules. *)
From
actris
.
logrel
Require
Export
term_typing_rules
.
From
iris
.
proofmode
Require
Import
tactics
.
...
...
theories/logrel/kind_tele.v
View file @
1130d468
(** This file defines kinded telescopes, which are used for representing binders
in session types. *)
From
stdpp
Require
Import
base
tactics
telescopes
.
From
actris
.
logrel
Require
Import
model
.
Set
Default
Proof
Using
"Type"
.
...
...
theories/logrel/lib/mutex.v
View file @
1130d468
(** This file defines a new semantic type former [mutex A], which is the type of
mutexes containing a value of type [A]. Mutexes are copyable, regardless of
whether the type contained in them is copyable. This makes them very useful for
sharing affine resources (such as channels) between multiple threads.
Internally, mutexes are implemented using a spin lock and a mutable reference.
The operations for spin locks that are used by the mutex are defined in Iris.
The following operations are supported on mutexes:
 [mutex_alloc]: Takes a value and wraps it in a mutex.
 [mutex_acquire]: Acquire the mutex and return the value contained in it.
 [mutex_release]: Release the mutex, storing a given value in it.
The typing rules for these operations additionally contain a type
[mutexguard A], which represents a mutex that has been acquired. The typing
rules for the operations require the [mutex] or [mutexguard] to be in a variable
(i.e., letbound), and the type of this variable in the typing context changes
as the mutex is acquired and released.
It is only possible to release a mutex after it has been opened. The
[mutexguard A] is not copyable, since that would allow a mutex to be released
multiple times after acquiring it once.
This type former is strongly inspired by the [Mutex] type in the standard
library of Rust, which has also been semantically modelled in the LambdaRust
project.
*)
From
iris
.
base_logic
.
lib
Require
Import
invariants
.
From
iris
.
heap_lang
Require
Export
spin_lock
.
From
actris
.
logrel
Require
Export
term_types
term_typing_judgment
subtyping
.
...
...
theories/logrel/model.v
View file @
1130d468
(** This file contains the definition of what semantic term types and semantic
session types are. A semantic term type is a unary (Iris) predicate on values
[val → iProp], as is customary in a logical relation for type soundness.
A semantic session type is an Actris protocol [iProto].
There is a single kinded variant [lty Σ k], which contains either a term type or a
session type, depending on the kind [k]. The reason for having a single type
containing both term types and session types is that it allows for uniform
definitions of polymorphic binders for term types and session types, instead of
having duplicated definitions.
This file also defines a COFE structure on semantic term types and session
types, which is required in order to define recursive term types and session
types. *)
From
iris
.
algebra
Require
Export
ofe
.
From
actris
.
channel
Require
Export
channel
.
...
...
theories/logrel/operators.v
View file @
1130d468
(** This file defines semantic typing lemmas for the operators of the language.
*)
From
actris
.
logrel
Require
Export
term_types
.
From
iris
.
heap_lang
Require
Import
proofmode
.
...
...
@@ 26,7 +28,7 @@ Section operators.
Proof
.
iIntros
(
v
).
by
iDestruct
1
as
(
b
)
">"
.
Qed
.
Global
Instance
lty_int_unboxed
:
LTyUnboxed
(
Σ
:
=
Σ
)
lty_int
.
Proof
.
iIntros
(
v
).
by
iDestruct
1
as
(
i
)
">"
.
Qed
.
Global
Instance
lty_ref_
mut
_unboxed
`
{
heapG
Σ
}
A
:
LTyUnboxed
(
ref_
mut
A
).
Global
Instance
lty_ref_
uniq
_unboxed
`
{
heapG
Σ
}
A
:
LTyUnboxed
(
ref_
uniq
A
).
Proof
.
iIntros
(
v
).
by
iDestruct
1
as
(
i
w
>)
"?"
.
Qed
.
Global
Instance
lty_ref_shr_unboxed
`
{
heapG
Σ
}
A
:
LTyUnboxed
(
ref_shr
A
).
Proof
.
iIntros
(
v
).
by
iDestruct
1
as
(
l
>)
"?"
.
Qed
.
...
...
theories/logrel/session_types.v
View file @
1130d468
(** This file defines the semantic interpretations of session types as Actris
protocols. It includes session types for sending and receiving with session
polymorphism, as well as nary choice. Recursive protocols are defined in
the model.v file. *)
From
iris
.
algebra
Require
Export
gmap
.
From
actris
.
logrel
Require
Export
model
kind_tele
.
From
actris
.
channel
Require
Export
channel
.
...
...
theories/logrel/subtyping.v
View file @
1130d468
From
actris
.
logrel
Require
Export
model
.
(** This file contains the definition of the semantic subtyping relation
[A <: B], where [A] and [B] can be either term types or session types, as
well as a semantic type equivalence relation [A <:> B], which is essentially
equivalent to having both [A <: B] and [B <: A]. Finally, the notion of a
*copyable type* is defined in terms of subtyping: a type [A] is copyable
when [A <: copy A]. *)
From
actris
.
logrel
Require
Export
model
term_types
.
Definition
lty_le
{
Σ
k
}
:
lty
Σ
k
→
lty
Σ
k
→
iProp
Σ
:
=
match
k
with
...
...
@@ 15,6 +21,10 @@ Arguments lty_bi_le : simpl never.
Infix
"<:>"
:
=
lty_bi_le
(
at
level
70
)
:
bi_scope
.
Instance
:
Params
(@
lty_bi_le
)
2
:
=
{}.
Definition
lty_copyable
{
Σ
}
(
A
:
ltty
Σ
)
:
iProp
Σ
:
=
tc_opaque
(
A
<
:
lty_copy
A
)%
I
.
Instance
:
Params
(@
lty_copyable
)
1
:
=
{}.
Section
subtyping
.
Context
{
Σ
:
gFunctors
}.
...
...
@@ 31,4 +41,9 @@ Section subtyping.
Proof
.
solve_proper
.
Qed
.
Global
Instance
lty_bi_le_proper
{
k
}
:
Proper
((
≡
)
==>
(
≡
)
==>
(
≡
))
(@
lty_bi_le
Σ
k
).
Proof
.
solve_proper
.
Qed
.
Global
Instance
lty_copyable_plain
A
:
Plain
(@
lty_copyable
Σ
A
).
Proof
.
rewrite
/
lty_copyable
/=.
apply
_
.
Qed
.
Global
Instance
lty_copyable_ne
:
NonExpansive
(@
lty_copyable
Σ
).
Proof
.
rewrite
/
lty_copyable
/=.
solve_proper
.
Qed
.
End
subtyping
.
theories/logrel/subtyping_rules.v
View file @
1130d468
(** This file defines all of the semantic subtyping rules for term types and
session types. *)
From
iris
.
bi
.
lib
Require
Import
core
.
From
iris
.
base_logic
.
lib
Require
Import
invariants
.
From
iris
.
proofmode
Require
Import
tactics
.
...
...
@@ 213,9 +215,9 @@ Section subtyping_rules.
iApply
"Hcopy"
.
Qed
.
Lemma
lty_le_ref_
mut
A1
A2
:
Lemma
lty_le_ref_
uniq
A1
A2
:
▷
(
A1
<
:
A2
)

∗
ref_
mut
A1
<
:
ref_
mut
A2
.
ref_
uniq
A1
<
:
ref_
uniq
A2
.
Proof
.
iIntros
"#H1"
(
v
)
"!>"
.
iDestruct
1
as
(
l
w
>)
"[Hl HA]"
.
iDestruct
(
"H1"
with
"HA"
)
as
"HA"
.
...
...
theories/logrel/term_types.v
View file @
1130d468
(** This file contains the definitions of the semantic interpretations of the
term type formers of the type system. The semantic interpretation of a type
(former) is a unary Iris predicate on values [val → iProp], which determines
when a value belongs to a certain type.
The following types are defined:
 [unit], [bool], [int]: basic types for unit, boolean and integer values,
respectively.
 [any]: inhabited by all values.
 [A ⊸ B]: the type of affine functions from [A] to [B]. Affine functions can
only be invoked once, since they might have captured affine resources.
 [A → B]: the type of nonaffine (copyable) functions from [A] to [B]. These
can be invoked any number of times. This is simply syntactic sugar for
[copy (A ⊸ B)].
 [A * B], [A + B], [∀ X, A], [∃ X, A]: products, sums, universal types,
existential types.
 [copy A]: inhabited by those values in the type [A] which are copyable. In the
case of functions, for instance, functions (closures) which capture affine
resources are not copyable, whereas functions that do not capture resources are.
 [copy A]: acts as a kind of "inverse" to [copy A]. More precisely, we have
that [copy (copy A) <:> A]. This type is used to indicate the results of
operations that might consume a resource, but do not always do so, depending
on whether the type [A] is copyable. Such operations result in a [copy A],
which can be turned into an [A] using subtyping when [A] is copyable.
 [ref_uniq A]: the type of uniquelyowned mutable references to a value of type [A].
Since the reference is guaranteed to be unique, it's possible for the type [A]
contained in the reference to change to a different type [B] by assigning to
the reference.
 [ref_shr A]: the type of shared mutable references to a value of type [A].
 [chan P]: the type of channels, governed by the session type [P].
In addition, some important properties, such as contractivity and
nonexpansiveness of these type formers is proved. This is important in order to
use these type formers to define recursive types. *)
From
iris
.
bi
.
lib
Require
Import
core
.
From
iris
.
base_logic
.
lib
Require
Import
invariants
.
From
iris
.
heap_lang
Require
Export
spin_lock
.
From
actris
.
logrel
Require
Export
subtyping
kind_tele
.
From
actris
.
logrel
Require
Export
model
kind_tele
.
From
actris
.
channel
Require
Export
channel
.
Definition
lty_any
{
Σ
}
:
ltty
Σ
:
=
Ltty
(
λ
w
,
True
%
I
).
Definition
lty_copy
{
Σ
}
(
A
:
ltty
Σ
)
:
ltty
Σ
:
=
Ltty
(
λ
w
,
□
ltty_car
A
w
)%
I
.
Definition
lty_copy_minus
{
Σ
}
(
A
:
ltty
Σ
)
:
ltty
Σ
:
=
Ltty
(
λ
w
,
coreP
(
ltty_car
A
w
)).
Definition
lty_copyable
{
Σ
}
(
A
:
ltty
Σ
)
:
iProp
Σ
:
=
tc_opaque
(
A
<
:
lty_copy
A
)%
I
.
Definition
lty_unit
{
Σ
}
:
ltty
Σ
:
=
Ltty
(
λ
w
,
⌜
w
=
#()
⌝
%
I
).
Definition
lty_bool
{
Σ
}
:
ltty
Σ
:
=
Ltty
(
λ
w
,
∃
b
:
bool
,
⌜
w
=
#
b
⌝
)%
I
.
Definition
lty_int
{
Σ
}
:
ltty
Σ
:
=
Ltty
(
λ
w
,
∃
n
:
Z
,
⌜
w
=
#
n
⌝
)%
I
.
Definition
lty_any
{
Σ
}
:
ltty
Σ
:
=
Ltty
(
λ
w
,
True
%
I
).
Definition
lty_arr
`
{
heapG
Σ
}
(
A1
A2
:
ltty
Σ
)
:
ltty
Σ
:
=
Ltty
(
λ
w
,
∀
v
,
▷
ltty_car
A1
v

∗
WP
w
v
{{
ltty_car
A2
}})%
I
.
...
...
@@ 29,7 +57,10 @@ Definition lty_forall `{heapG Σ} {k} (C : lty Σ k → ltty Σ) : ltty Σ :=
Definition
lty_exist
{
Σ
k
}
(
C
:
lty
Σ
k
→
ltty
Σ
)
:
ltty
Σ
:
=
Ltty
(
λ
w
,
∃
A
,
▷
ltty_car
(
C
A
)
w
)%
I
.
Definition
lty_ref_mut
`
{
heapG
Σ
}
(
A
:
ltty
Σ
)
:
ltty
Σ
:
=
Ltty
(
λ
w
,
Definition
lty_copy
{
Σ
}
(
A
:
ltty
Σ
)
:
ltty
Σ
:
=
Ltty
(
λ
w
,
□
ltty_car
A
w
)%
I
.
Definition
lty_copy_minus
{
Σ
}
(
A
:
ltty
Σ
)
:
ltty
Σ
:
=
Ltty
(
λ
w
,
coreP
(
ltty_car
A
w
)).
Definition
lty_ref_uniq
`
{
heapG
Σ
}
(
A
:
ltty
Σ
)
:
ltty
Σ
:
=
Ltty
(
λ
w
,
∃
(
l
:
loc
)
(
v
:
val
),
⌜
w
=
#
l
⌝
∗
l
↦
v
∗
▷
ltty_car
A
v
)%
I
.
Definition
ref_shrN
:
=
nroot
.@
"shr_ref"
.
Definition
lty_ref_shr
`
{
heapG
Σ
}
(
A
:
ltty
Σ
)
:
ltty
Σ
:
=
Ltty
(
λ
w
,
...
...
@@ 40,13 +71,12 @@ Definition lty_chan `{heapG Σ, chanG Σ} (P : lsty Σ) : ltty Σ :=
Instance
:
Params
(@
lty_copy
)
1
:
=
{}.
Instance
:
Params
(@
lty_copy_minus
)
1
:
=
{}.
Instance
:
Params
(@
lty_copyable
)
1
:
=
{}.
Instance
:
Params
(@
lty_arr
)
2
:
=
{}.
Instance
:
Params
(@
lty_prod
)
1
:
=
{}.
Instance
:
Params
(@
lty_sum
)
1
:
=
{}.
Instance
:
Params
(@
lty_forall
)
2
:
=
{}.
Instance
:
Params
(@
lty_sum
)
1
:
=
{}.
Instance
:
Params
(@
lty_ref_
mut
)
2
:
=
{}.
Instance
:
Params
(@
lty_ref_
uniq
)
2
:
=
{}.
Instance
:
Params
(@
lty_ref_shr
)
2
:
=
{}.
Instance
:
Params
(@
lty_chan
)
3
:
=
{}.
...
...
@@ 66,7 +96,7 @@ Notation "∀ A1 .. An , C" :=
Notation
"∃ A1 .. An , C"
:
=
(
lty_exist
(
λ
A1
,
..
(
lty_exist
(
λ
An
,
C
%
lty
))
..))
:
lty_scope
.
Notation
"'ref_
mut
' A"
:
=
(
lty_ref_
mut
A
)
(
at
level
10
)
:
lty_scope
.
Notation
"'ref_
uniq
' A"
:
=
(
lty_ref_
uniq
A
)
(
at
level
10
)
:
lty_scope
.
Notation
"'ref_shr' A"
:
=
(
lty_ref_shr
A
)
(
at
level
10
)
:
lty_scope
.
Notation
"'chan' A"
:
=
(
lty_chan
A
)
(
at
level
10
)
:
lty_scope
.
...
...
@@ 80,11 +110,6 @@ Section term_types.
Global
Instance
lty_copy_minus_ne
:
NonExpansive
(@
lty_copy_minus
Σ
).
Proof
.
solve_proper
.
Qed
.
Global
Instance
lty_copyable_plain
A
:
Plain
(
lty_copyable
A
).
Proof
.
rewrite
/
lty_copyable
/=.
apply
_
.
Qed
.
Global
Instance
lty_copyable_ne
:
NonExpansive
(@
lty_copyable
Σ
).
Proof
.
rewrite
/
lty_copyable
/=.
solve_proper
.
Qed
.
Global
Instance
lty_arr_contractive
`
{
heapG
Σ
}
n
:
Proper
(
dist_later
n
==>
dist_later
n
==>
dist
n
)
lty_arr
.
Proof
.
...
...
@@ 122,9 +147,9 @@ Section term_types.
Proper
(
pointwise_relation
_
(
dist
n
)
==>
dist
n
)
(@
lty_exist
Σ
k
).
Proof
.
solve_proper
.
Qed
.
Global
Instance
lty_ref_
mut
_contractive
`
{
heapG
Σ
}
:
Contractive
lty_ref_
mut
.
Global
Instance
lty_ref_
uniq
_contractive
`
{
heapG
Σ
}
:
Contractive
lty_ref_
uniq
.
Proof
.
solve_contractive
.
Qed
.
Global
Instance
lty_ref_
mut
_ne
`
{
heapG
Σ
}
:
NonExpansive
lty_ref_
mut
.
Global
Instance
lty_ref_
uniq
_ne
`
{
heapG
Σ
}
:
NonExpansive
lty_ref_
uniq
.
Proof
.
solve_proper
.
Qed
.
Global
Instance
lty_ref_shr_contractive
`
{
heapG
Σ
}
:
Contractive
lty_ref_shr
.
...
...
theories/logrel/term_typing_judgment.v
View file @
1130d468
(** This file contains the definitions of the semantic typing relation
[Γ ⊨ e : A ⫤ Γ'], indicating that in context [Γ], the expression [e] has type
[A], producing a new context [Γ']. The context is allowed to change to
accomodate things like changing the type of a channel after a receive.
In addition, we use the adequacy of Iris in order to show type soundness:
programs which satisfy the semantic typing relation are safe. That is,
semantically welltyped programs do not get stuck. *)
From
iris
.
heap_lang
Require
Import
metatheory
adequacy
.
From
actris
.
logrel
Require
Export
term_types
.
From
actris
.
logrel
Require
Import
environments
.
...
...
theories/logrel/term_typing_rules.v
View file @
1130d468
(** This file defines all of the semantic typing lemmas for term types. Most of
these lemmas are semantic versions of the syntactic typing judgments typically
found in a syntactic type system. *)
From
stdpp
Require
Import
pretty
.
From
iris
.
bi
.
lib
Require
Import
core
.
From
iris
.
base_logic
.
lib
Require
Import
invariants
.
...
...
@@ 255,11 +258,10 @@ Section properties.
iIntros
(
w
)
"[$ HΓ3]"
.
by
iApply
env_ltyped_delete
.
Qed
.
(** Mutable Reference properties *)
(** Mutable Unique Reference properties *)
Lemma
ltyped_alloc
Γ
1
Γ
2
e
A
:
(
Γ
1
⊨
e
:
A
⫤
Γ
2
)

∗
(
Γ
1
⊨
ref
e
:
ref_
mut
A
⫤
Γ
2
).
(
Γ
1
⊨
ref
e
:
ref_
uniq
A
⫤
Γ
2
).
Proof
.
iIntros
"#He"
(
vs
)
"!> HΓ1 /="
.
wp_bind
(
subst_map
vs
e
).
...
...
@@ 270,8 +272,8 @@ Section properties.
Qed
.
Lemma
ltyped_load
Γ
(
x
:
string
)
A
:
Γ
!!
x
=
Some
(
ref_
mut
A
)%
lty
→
⊢
Γ
⊨
!
x
:
A
⫤
<[
x
:
=
(
ref_
mut
(
copy

A
))%
lty
]>
Γ
.
Γ
!!
x
=
Some
(
ref_
uniq
A
)%
lty
→
⊢
Γ
⊨
!
x
:
A
⫤
<[
x
:
=
(
ref_
uniq
(
copy

A
))%
lty
]>
Γ
.
Proof
.
iIntros
(
Hx
vs
)
"!> HΓ"
.
iDestruct
(
env_ltyped_lookup
with
"HΓ"
)
as
(
v
Hv
)
"[HA HΓ]"
;
first
done
.
...
...
@@ 281,7 +283,7 @@ Section properties.
iAssert
(
ltty_car
(
copy

A
)
w
)%
lty
as
"#HAm"
.
{
iApply
coreP_intro
.
iApply
"Hw"
.
}
iFrame
"Hw"
.
iAssert
(
ltty_car
(
ref_
mut
(
copy

A
))%
lty
#
l
)
with
"[Hl]"
as
"HA"
.
iAssert
(
ltty_car
(
ref_
uniq
(
copy

A
))%
lty
#
l
)
with
"[Hl]"
as
"HA"
.
{
iExists
l
,
w
.
iSplit
=>//.
iFrame
"Hl HAm"
.
}
iDestruct
(
env_ltyped_insert
_
_
x
with
"HA HΓ"
)
as
"HΓ"
.
rewrite
/
binder_insert
insert_delete
(
insert_id
_
_
_
Hv
).
...
...
@@ 289,9 +291,9 @@ Section properties.
Qed
.
Lemma
ltyped_store
Γ
Γ
'
(
x
:
string
)
e
A
B
:
Γ
'
!!
x
=
Some
(
ref_
mut
A
)%
lty
→
Γ
'
!!
x
=
Some
(
ref_
uniq
A
)%
lty
→
(
Γ
⊨
e
:
B
⫤
Γ
'
)

∗
Γ
⊨
x
<
e
:
()
⫤
<[
x
:
=
(
ref_
mut
B
)%
lty
]>
Γ
'
.
Γ
⊨
x
<
e
:
()
⫤
<[
x
:
=
(
ref_
uniq
B
)%
lty
]>
Γ
'
.
Proof
.
iIntros
(
Hx
)
"#He"
.
iIntros
(
vs
)
"!> HΓ /="
.
wp_bind
(
subst_map
vs
e
).
...
...
@@ 300,16 +302,16 @@ Section properties.
rewrite
Hw
.
iDestruct
"HA"
as
(
l
v'
>)
"[Hl HA]"
.
wp_store
.
iSplitR
;
first
done
.
iAssert
(
ltty_car
(
ref_
mut
B
)%
lty
#
l
)
with
"[Hl HB]"
as
"HB"
.
iAssert
(
ltty_car
(
ref_
uniq
B
)%
lty
#
l
)
with
"[Hl HB]"
as
"HB"
.
{
iExists
l
,
v
.
iSplit
=>//.
iFrame
"Hl HB"
.
}
iDestruct
(
env_ltyped_insert
_
_
x
with
"HB HΓ'"
)
as
"HΓ'"
.
rewrite
/
binder_insert
insert_delete
(
insert_id
_
_
_
Hw
).
iFrame
"HΓ'"
.
Qed
.
(** Shared Reference properties *)
(**
Mutable
Shared Reference properties *)
Lemma
ltyped_upgrade_shared
Γ
Γ
'
e
A
:
(
Γ
⊨
e
:
ref_
mut
(
copy
A
)
⫤
Γ
'
)

∗
(
Γ
⊨
e
:
ref_
uniq
(
copy
A
)
⫤
Γ
'
)

∗
Γ
⊨
e
:
ref_shr
A
⫤
Γ
'
.
Proof
.
iIntros
"#He"
(
vs
)
"!> HΓ"
.
iApply
wp_fupd
.
...
...
@@ 397,6 +399,7 @@ Section properties.
Qed
.
End
with_spawn
.
(** Channel properties *)
Section
with_chan
.
Context
`
{
chanG
Σ
}.
...
...
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