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Iris
Iron
Commits
1a34a493
Commit
1a34a493
authored
Oct 31, 2018
by
Robbert Krebbers
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...
@@ 14,69 +14,68 @@ Iron has been built and tested with the following dependencies
...
@@ 14,69 +14,68 @@ Iron has been built and tested with the following dependencies
## Directory Structure
## Directory Structure

In
`
theories/algebra
`
two new cameras are defined.

In
[
theories/algebra
](
theories/algebra
)
two new cameras are defined.
1.
Improper fractions as a camera without identity with addition as
1.
Improper fractions as a camera without identity with addition as
the operation are defined in
`
theories/algebra/vfrac.v
`
.
the operation are defined in
[
theories/algebra/vfrac.v
](
theories/algebra/vfrac.v
)
.
2.
The fractional authoritative camera described in Section 5 built
2.
The fractional authoritative camera described in Section 5 built
with improper fractions is defined in
with improper fractions is defined in
`
theories/algebra/vfrac_auth.v
`
.
[
theories/algebra/vfrac_auth.v
](
theories/algebra/vfrac_auth.v
)
.

The semantics of the connectives of
the lif
te
d
logic are given in

The semantics of the connectives of
fractional predica
te
s
logic are given in
`
theories/bi/fracpred.v
`
.
[
theories/bi/fracpred.v
](
theories/bi/fracpred.v
)
.
This file does not contain a description of the lifted program
This file does not contain a description of the lifted program
logic but instead contains the definitions of ∧, ∗, ∀, and other
logic but instead contains the definitions of ∧, ∗, ∀, and other
the other connectives. It also contains all the rules of the
the other connectives. It also contains all the rules of the
specific to this logic that are used later.
specific to this logic that are used later.

The machinery for connecting the generalized proofmode from

The machinery for connecting the generalized proofmode/MoSeL from to
`iriscoq`
to fractional predicates is contained in
fractional predicates is contained in (theories/proofmode)[theories/proofmode].
`theories/proofmode`
.

In
`
theories/iron_logic
`
much of the core Iron logic
discussed

In
(theories/iron_logic)[
theories/iron_logic
]
much of the core Iron logic
in Section 2 is defined.
discussed
in Section 2 is defined.
*
Uniformity with respect to fractions is defined in
*
_
Uniformity
_
with respect to fractions is defined in
`
theories/iron_logic/iron.v
`
as
`Uniform`
and
[
theories/iron_logic/iron.v
](
theories/iron_logic/iron.v
)
as
`Uniform`
and
several closure properties of it are proved.
several closure properties of it are proved.
*
Trackable invariants as discussed in Section 2.1 are formalized
*
_
Trackable invariants
_
as discussed in Section 2.1 are formalized
in
`
theories/iron_logic/fcinv.v
`
.
in
[
theories/iron_logic/fcinv.v
](
theories/iron_logic/fcinv.v
)
.
*
The definition of weakest preconditions from Section 4 is in
*
The definition of weakest preconditions from Section 4 is in
`
theories/iron_logic/weakestpre.v
`
.
[
theories/iron_logic/weakestpre.v
](
theories/iron_logic/weakestpre.v
)
.

The formalization specific to the λref,conc is in

The formalization specific to the λref,conc is in
`
theories/heap_lang
`
.
[
theories/heap_lang
](
theories/heap_lang
)
.
*
The definition of the heap in terms of ghost state from Section
*
The definition of the heap in terms of ghost state from Section
5 is in
5 is in
`
theories/heap_lang/heap.v
`
as
`heapG`
. So too
are
[
theories/heap_lang/heap.v
](
theories/heap_lang/heap.v
)
as
`heapG`
. So too
the definitions of ↦ and
e
(in the formalization called
`perm`
).
are
the definitions of ↦ and
𝖊
(in the formalization called
`perm`
).
*
The theorems stated in Section 5 about updates to the heap ghost
*
The theorems stated in Section 5 about updates to the heap ghost
state are proven in
`
theories/heap_lang/heap.v
`
.
state are proven in
(theories/heap_lang/heap.v)[
theories/heap_lang/heap.v
]
.
*
The state interpretation from Section 5 is defined in
*
The state interpretation from Section 5 is defined in
`
theories/heap_lang/heap.v
`
as
`heap_ctx`
.
[
theories/heap_lang/heap.v
](
theories/heap_lang/heap.v
)
as
`heap_ctx`
.
*
Theorems 2.1, 2.2, 4.1, and 4.2 are proven in
*
Theorems 2.1, 2.2, 4.1, and 4.2 are proven in
`
theories/heap_lang/adequacy.v
`
.
[
theories/heap_lang/adequacy.v
](
theories/heap_lang/adequacy.v
)
.
*
The operational semantics from Figure 4 are defined in
*
The operational semantics from Figure 4 are defined in
`
theories/heap_lang/lang.v
`
.
[
theories/heap_lang/lang.v
](
theories/heap_lang/lang.v
)
.
*
The rules from Figures 1, 2, 3, and 5 are proven in
*
The rules from Figures 1, 2, 3, and 5 are proven in
`
theories/heap_lang/lifting.v
`
.
[
theories/heap_lang/lifting.v
](
theories/heap_lang/lifting.v
)
.

All of the examples of the paper are formalized and may be found in

All of the examples of the paper are formalized and may be found in
`
theories/heap_lang/lib/
`
. All of the examples are
formalized
[
theories/heap_lang/lib/
](
theories/heap_lang/lib/
)
. All of the examples are
purely within the lifted logic. There is no fraction accounting in
formalized
purely within the lifted logic. There is no fraction accounting in
the proofs and no significant bookkeeping beyond what is found in
the proofs and no significant bookkeeping beyond what is found in
vanilla Iris.
vanilla Iris.
As mentioned in the paper, a small portion of
`par`
cannot be
As mentioned in the paper, a small portion of
`par`
cannot be
formalized in
formalized in
the lifted logic but in the formalization this is
the lifted logic but in the formalization this is
factored out into
`spawn`
factored out into
`spawn`
in
`
theories/heap_lang/lib/spawn.v
`
.
in
[
theories/heap_lang/lib/spawn.v
](
theories/heap_lang/lib/spawn.v
)
*
The example from 3.1 is in
`
theories/heap_lang/lib/resource_transfer_par.v
`
.
*
The example from 3.1 is in
[
theories/heap_lang/lib/resource_transfer_par.v
](
theories/heap_lang/lib/resource_transfer_par.v
)
.
*
The example from 3.2 is in
`
theories/heap_lang/lib/resource_transfer_fork.v
`
.
*
The example from 3.2 is in
[
theories/heap_lang/lib/resource_transfer_fork.v
](
theories/heap_lang/lib/resource_transfer_fork.v
)
.
*
The example from 3.3 is in
`
theories/heap_lang/lib/message_passing.v
`
.
*
The example from 3.3 is in
[
theories/heap_lang/lib/message_passing.v
](
theories/heap_lang/lib/message_passing.v
)
.
*
The example from 3.4 is in
`
theories/heap_lang/lib/message_passing_example.v
`
.
*
The example from 3.4 is in
[
theories/heap_lang/lib/message_passing_example.v
](
theories/heap_lang/lib/message_passing_example.v
)
.
*
The example from 3.5 is in
`
theories/heap_lang/lib/par.v
`
.
*
The example from 3.5 is in
[
theories/heap_lang/lib/par.v
](
theories/heap_lang/lib/resource_transfer_par.v
)
.
Note that
`spawn.v`
,
`resource_transfer_par.v`
, and
`resource_transfer_fork.v`
Note that
`spawn.v`
,
`resource_transfer_par.v`
, and
`resource_transfer_fork.v`
use the same state transition system (from Figure 3). This is formalized in
use the same state transition system (from Figure 3). This is formalized in
`
theories/heap_lang/lib/transfer_resource_sts.v
`
.
[
theories/heap_lang/lib/transfer_resource_sts.v
](
theories/heap_lang/lib/transfer_resource_sts.v
)
.
## Differences Between the Formalization and The Paper
## Differences Between the Formalization and The Paper
...
@@ 152,9 +151,9 @@ This can be used to derive `LINVALLOC` when used in conjunction with
...
@@ 152,9 +151,9 @@ This can be used to derive `LINVALLOC` when used in conjunction with
There is a correspondence between the invariant rules presented in the
There is a correspondence between the invariant rules presented in the
paper with Hoare triples and those in the formalization.
paper with Hoare triples and those in the formalization.

`TINVALLOC`
and
`LTINVALLOC`
follow from
`fcinv_alloc_named`
.

`TINVALLOC`
and
`LTINVALLOC`
follow from
`fcinv_alloc_named`
.

`TINVOPEN`
and
`LTINVOPEN`
follow from
`fcinv_open`
.

`TINVOPEN`
and
`LTINVOPEN`
follow from
`fcinv_open`
.

`TINVDEALLOC`
and
`LTINVDEALLOC`
follow from
`fcinv_cancel`
.

`TINVDEALLOC`
and
`LTINVDEALLOC`
follow from
`fcinv_cancel`
.
All of these theorems are proven in
`theories/iron_logic/fcinv.v`
.
All of these theorems are proven in
`theories/iron_logic/fcinv.v`
.
...
@@ 172,63 +171,63 @@ The format of the table is as follows: Name of
...
@@ 172,63 +171,63 @@ The format of the table is as follows: Name of
Theorem/Rule/Definition/Proposition, the name in the formalization,
Theorem/Rule/Definition/Proposition, the name in the formalization,
and the file in the formalization.
and the file in the formalization.

The language definition in Section 2,
`expr`
,
`theories/heap_lang/lang.v`

The language definition in Section 2,
`expr`
,
`theories/heap_lang/lang.v`

`e`
and
`↦`
,
`perm`
and
`↦`
,
`theories/heap_lang/heap.v`

`e`
and
`↦`
,
`perm`
and
`↦`
,
`theories/heap_lang/heap.v`

Trackable invariants,
`fcinv`
,
`theories/iron_logic/fcinv.v`

Trackable invariants,
`fcinv`
,
`theories/iron_logic/fcinv.v`

`OPerm(, )`
,
`fcinv_own`
,
`theories/iron_logic/fcinv.v`

`OPerm(, )`
,
`fcinv_own`
,
`theories/iron_logic/fcinv.v`

`DPerm(, )`
,
`fcinv_cancel_own`
,
`theories/iron_logic/fcinv.v`

`DPerm(, )`
,
`fcinv_cancel_own`
,
`theories/iron_logic/fcinv.v`

`HOAREFRAME`
,
`hoare_frame_r`
,
`iriscoq/theories/program_logic/hoare.v`

`HOAREFRAME`
,
`hoare_frame_r`
,
`iriscoq/theories/program_logic/hoare.v`

`HOAREVAL`
,
`ht_val`
,
`iriscoq/theories/program_logic/hoare.v`

`HOAREVAL`
,
`ht_val`
,
`iriscoq/theories/program_logic/hoare.v`

`HOAREλ`
,
`pure_rec`
,
`theories/heap_lang/lifting.v`

`HOAREλ`
,
`pure_rec`
,
`theories/heap_lang/lifting.v`

`HOAREBIND`
,
`ht_bind`
,
`iriscoq/theories/program_logic/hoare.v`

`HOAREBIND`
,
`ht_bind`
,
`iriscoq/theories/program_logic/hoare.v`

`EMPSPLIT`
,
`perm_split`
,
`theories/heap_lang/heap.v`

`EMPSPLIT`
,
`perm_split`
,
`theories/heap_lang/heap.v`

`PTSPLIT`
,
`mapsto_uniform`
,
`theories/heap_lang/heap.v`

`PTSPLIT`
,
`mapsto_uniform`
,
`theories/heap_lang/heap.v`

`PTDISJ`
,
`mapsto_valid_2`
,
`theories/heap_lang/heap.v`

`PTDISJ`
,
`mapsto_valid_2`
,
`theories/heap_lang/heap.v`

`HOAREALLOC`
,
`wp_alloc`
,
`theories/heap_lang/lifting.v`

`HOAREALLOC`
,
`wp_alloc`
,
`theories/heap_lang/lifting.v`

`HOAREFREE`
,
`wp_free`
,
`theories/heap_lang/lifting.v`

`HOAREFREE`
,
`wp_free`
,
`theories/heap_lang/lifting.v`

`HOARELOAD`
,
`wp_load`
,
`theories/heap_lang/lifting.v`

`HOARELOAD`
,
`wp_load`
,
`theories/heap_lang/lifting.v`

`HOARESTORE`
,
`wp_store`
,
`theories/heap_lang/lifting.v`

`HOARESTORE`
,
`wp_store`
,
`theories/heap_lang/lifting.v`

`HOAREFORKEMP`
/
`HOAREFORKTRUE`
,
`wp_fork`
,
`theories/heap_lang/lifting.v`

`HOAREFORKEMP`
/
`HOAREFORKTRUE`
,
`wp_fork`
,
`theories/heap_lang/lifting.v`

`INVDUP`
,
`inv_persistent`
,
`theories/heap_lang/lifting.v`

`INVDUP`
,
`inv_persistent`
,
`theories/heap_lang/lifting.v`

`INVALLOC`
,
`inv_alloc`
,
`iriscoq/theories/base_logic/lib/invariants.v`

`INVALLOC`
,
`inv_alloc`
,
`iriscoq/theories/base_logic/lib/invariants.v`

`INVOPEN`
,
`inv_open`
,
`iriscoq/theories/base_logic/lib/invariants.v`

`INVOPEN`
,
`inv_open`
,
`iriscoq/theories/base_logic/lib/invariants.v`

`TINVSPLIT`
,
`fcinv_own_fractional`
,
`theories/iron_logic/fcinv.v`

`TINVSPLIT`
,
`fcinv_own_fractional`
,
`theories/iron_logic/fcinv.v`

`TINVDUP`
,
`fcinv_persistent`
,
`theories/iron_logic/fcinv.v`

`TINVDUP`
,
`fcinv_persistent`
,
`theories/iron_logic/fcinv.v`

`TINVALLOC`
,
`fcinv_alloc_named`
,
`theories/iron_logic/fcinv.v`

`TINVALLOC`
,
`fcinv_alloc_named`
,
`theories/iron_logic/fcinv.v`

`TINVOPEN`
,
`fcinv_open`
,
`theories/iron_logic/fcinv.v`

`TINVOPEN`
,
`fcinv_open`
,
`theories/iron_logic/fcinv.v`

`TINVDEALLOC`
,
`fcinv_cancel`
,
`theories/iron_logic/fcinv.v`

`TINVDEALLOC`
,
`fcinv_cancel`
,
`theories/iron_logic/fcinv.v`

Uniform with respect to fractions,
`Uniform`
,
`theories/iron_logic/iron.v`

Uniform with respect to fractions,
`Uniform`
,
`theories/iron_logic/iron.v`

`HOARECONS`
,
`ht_vs`
,
`iriscoq/theories/program_logic/hoare.v`

`HOARECONS`
,
`ht_vs`
,
`iriscoq/theories/program_logic/hoare.v`

The rules from Figure 4,
`head_step`
,
`theories/heap_lang/lang.v`

The rules from Figure 4,
`head_step`
,
`theories/heap_lang/lang.v`

Theorem 2.1,
`heap_adequacy`
,
`theories/heap_lang/adequacy.v`

Theorem 2.1,
`heap_adequacy`
,
`theories/heap_lang/adequacy.v`

Theorem 2.2,
`heap_strong_adequacy`
,
`theories/heap_lang/adequacy.v`

Theorem 2.2,
`heap_strong_adequacy`
,
`theories/heap_lang/adequacy.v`

`HOAREPAR`
,
`par_spec`
,
`theories/heap_lang/lib/par.v`

`HOAREPAR`
,
`par_spec`
,
`theories/heap_lang/lib/par.v`

The example from 3.1,
`transfer_works1`
,
`theories/heap_lang/lib/resource_tranfer_par.v`

The example from 3.1,
`transfer_works1`
,
`theories/heap_lang/lib/resource_tranfer_par.v`

The example from 3.2,
`transfer_works1`
,
`theories/heap_lang/lib/resource_tranfer_fork.v`

The example from 3.2,
`transfer_works1`
,
`theories/heap_lang/lib/resource_tranfer_fork.v`

The example from 3.3, Several theorems,
`theories/heap_lang/lib/message_passing.v`

The example from 3.3, Several theorems,
`theories/heap_lang/lib/message_passing.v`

The example from 3.4,
`program_spec`
,
`theories/heap_lang/lib/message_passing_example.v`

The example from 3.4,
`program_spec`
,
`theories/heap_lang/lib/message_passing_example.v`

The example from 3.5, Several theorems,
`theories/heap_lang/lib/{spawn, par}.v`

The example from 3.5, Several theorems,
`theories/heap_lang/lib/{spawn, par}.v`

Definitions of lifted connectives, Several definitions,
`theories/bi/fracpred.v`

Definitions of lifted connectives, Several definitions,
`theories/bi/fracpred.v`

Definition of lifted
`↦`
,
`↦`
,
`theories/heap_lang/heap.v`

Definition of lifted
`↦`
,
`↦`
,
`theories/heap_lang/heap.v`

`LHOAREFRAME`
,
`iron_wp_frame_r`
,
`iriscoq/theories/program_logic/hoare.v`

`LHOAREFRAME`
,
`iron_wp_frame_r`
,
`iriscoq/theories/program_logic/hoare.v`

`LHOAREVAL`
,
`iron_wp_val`
,
`iriscoq/theories/program_logic/hoare.v`

`LHOAREVAL`
,
`iron_wp_val`
,
`iriscoq/theories/program_logic/hoare.v`

`LHOAREλ`
,
`pure_rec`
,
`theories/heap_lang/lifting.v`

`LHOAREλ`
,
`pure_rec`
,
`theories/heap_lang/lifting.v`

`LHOAREBIND`
,
`iron_wp_bind`
,
`iriscoq/theories/program_logic/hoare.v`

`LHOAREBIND`
,
`iron_wp_bind`
,
`iriscoq/theories/program_logic/hoare.v`

`LPTDISJ`
,
`mapsto_valid_2`
,
`theories/heap_lang/heap.v`

`LPTDISJ`
,
`mapsto_valid_2`
,
`theories/heap_lang/heap.v`

`LHOAREALLOC`
,
`iron_wp_alloc`
,
`theories/heap_lang/lifting.v`

`LHOAREALLOC`
,
`iron_wp_alloc`
,
`theories/heap_lang/lifting.v`

`LHOAREFREE`
,
`iron_wp_free`
,
`theories/heap_lang/lifting.v`

`LHOAREFREE`
,
`iron_wp_free`
,
`theories/heap_lang/lifting.v`

`LHOARELOAD`
,
`iron_wp_load`
,
`theories/heap_lang/lifting.v`

`LHOARELOAD`
,
`iron_wp_load`
,
`theories/heap_lang/lifting.v`

`LHOARESTORE`
,
`iron_wp_store`
,
`theories/heap_lang/lifting.v`

`LHOARESTORE`
,
`iron_wp_store`
,
`theories/heap_lang/lifting.v`

`LHOAREFORK`
,
`iron_wp_fork`
,
`theories/heap_lang/lifting.v`

`LHOAREFORK`
,
`iron_wp_fork`
,
`theories/heap_lang/lifting.v`

`LTINVSPLIT`
,
`fcinv_own_fractional`
,
`theories/iron_logic/fcinv.v`

`LTINVSPLIT`
,
`fcinv_own_fractional`
,
`theories/iron_logic/fcinv.v`

`LTINVDUP`
,
`fcinv_persistent`
,
`theories/iron_logic/fcinv.v`

`LTINVDUP`
,
`fcinv_persistent`
,
`theories/iron_logic/fcinv.v`

`LTINVALLOC`
,
`fcinv_alloc_named`
,
`theories/iron_logic/fcinv.v`

`LTINVALLOC`
,
`fcinv_alloc_named`
,
`theories/iron_logic/fcinv.v`

`LTINVOPEN`
,
`fcinv_open`
,
`theories/iron_logic/fcinv.v`

`LTINVOPEN`
,
`fcinv_open`
,
`theories/iron_logic/fcinv.v`

`LTINVDEALLOC`
,
`fcinv_cancel`
,
`theories/iron_logic/fcinv.v`

`LTINVDEALLOC`
,
`fcinv_cancel`
,
`theories/iron_logic/fcinv.v`

Definition of Hoare triples,
`iron_wp`
,
`theories/iron_logic/weakestpre.v`

Definition of Hoare triples,
`iron_wp`
,
`theories/iron_logic/weakestpre.v`

Theorem 4.1,
`heap_adequacy`
,
`theories/heap_lang/adequacy.v`

Theorem 4.1,
`heap_adequacy`
,
`theories/heap_lang/adequacy.v`

Theorem 4.2,
`heap_strong_adequacy`
,
`theories/heap_lang/adequacy.v`

Theorem 4.2,
`heap_strong_adequacy`
,
`theories/heap_lang/adequacy.v`

Definition of WP in Section 5,
`wp_def`
,
`iriscoq/theories/program_logic/weakestpre.v`

Definition of WP in Section 5,
`wp_def`
,
`iriscoq/theories/program_logic/weakestpre.v`

Definition of state interp from Section 5,
`heap_ctx`
,
`theories/heap_lang/heap.v`

Definition of state interp from Section 5,
`heap_ctx`
,
`theories/heap_lang/heap.v`

Theorem 5.1,
`wp_strong_all_adequacy`
,
`iriscoq/theories/program_logic/adequacy.v`

Theorem 5.1,
`wp_strong_all_adequacy`
,
`iriscoq/theories/program_logic/adequacy.v`
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