In-memory representation of values.
Require Import Coqlib.
Require Import Zbits.
Require Archi.
Require Import AST.
Require Import Integers.
Require Import Floats.
Require Import Values.
Properties of memory chunks
Memory reads and writes are performed by quantities called memory chunks,
encoding the type, size and signedness of the chunk being addressed.
The following functions extract the size information from a chunk.
Definition size_chunk (
chunk:
memory_chunk) :
Z :=
match chunk with
|
Mint8signed => 1
|
Mint8unsigned => 1
|
Mint16signed => 2
|
Mint16unsigned => 2
|
Mint32 => 4
|
Mint64 => 8
|
Mfloat32 => 4
|
Mfloat64 => 8
|
Many32 => 4
|
Many64 => 8
end.
Lemma size_chunk_pos:
forall chunk,
size_chunk chunk > 0.
Proof.
intros. destruct chunk; simpl; lia.
Qed.
Definition size_chunk_nat (
chunk:
memory_chunk) :
nat :=
Z.to_nat(
size_chunk chunk).
Lemma size_chunk_conv:
forall chunk,
size_chunk chunk =
Z.of_nat (
size_chunk_nat chunk).
Proof.
intros. destruct chunk; reflexivity.
Qed.
Lemma size_chunk_nat_pos:
forall chunk,
exists n,
size_chunk_nat chunk =
S n.
Proof.
Lemma size_chunk_Mptr:
size_chunk Mptr =
if Archi.ptr64 then 8
else 4.
Proof.
Memory reads and writes must respect alignment constraints:
the byte offset of the location being addressed should be an exact
multiple of the natural alignment for the chunk being addressed.
This natural alignment is defined by the following
align_chunk function. Some target architectures
(e.g. PowerPC and x86) have no alignment constraints, which we could
reflect by taking align_chunk chunk = 1. However, other architectures
have stronger alignment requirements. The following definition is
appropriate for PowerPC, ARM and x86.
Definition align_chunk (
chunk:
memory_chunk) :
Z :=
match chunk with
|
Mint8signed => 1
|
Mint8unsigned => 1
|
Mint16signed => 2
|
Mint16unsigned => 2
|
Mint32 => 4
|
Mint64 => 8
|
Mfloat32 => 4
|
Mfloat64 => 4
|
Many32 => 4
|
Many64 => 4
end.
Lemma align_chunk_pos:
forall chunk,
align_chunk chunk > 0.
Proof.
intro. destruct chunk; simpl; lia.
Qed.
Lemma align_chunk_Mptr:
align_chunk Mptr =
if Archi.ptr64 then 8
else 4.
Proof.
Lemma align_size_chunk_divides:
forall chunk, (
align_chunk chunk |
size_chunk chunk).
Proof.
intros.
destruct chunk;
simpl;
try apply Z.divide_refl;
exists 2;
auto.
Qed.
Lemma align_le_divides:
forall chunk1 chunk2,
align_chunk chunk1 <=
align_chunk chunk2 -> (
align_chunk chunk1 |
align_chunk chunk2).
Proof.
intros.
destruct chunk1;
destruct chunk2;
simpl in *;
solve [
extlia
|
apply Z.divide_refl
|
exists 2;
reflexivity
|
exists 4;
reflexivity
|
exists 8;
reflexivity ].
Qed.
Inductive quantity :
Type :=
Q32 |
Q64.
Definition quantity_eq (
q1 q2:
quantity) : {
q1 =
q2} + {
q1 <>
q2}.
Proof.
decide equality. Defined.
Global Opaque quantity_eq.
Definition size_quantity_nat (
q:
quantity) :=
match q with Q32 => 4%
nat |
Q64 => 8%
nat end.
Lemma size_quantity_nat_pos:
forall q,
exists n,
size_quantity_nat q =
S n.
Proof.
intros. destruct q; [exists 3%nat | exists 7%nat]; auto.
Qed.
Memory values
A ``memory value'' is a byte-sized quantity that describes the current
content of a memory cell. It can be either:
-
a concrete 8-bit integer;
-
a byte-sized fragment of an opaque value;
-
the special constant Undef that represents uninitialized memory.
Values stored in memory cells.
Inductive memval:
Type :=
|
Undef:
memval
|
Byte:
byte ->
memval
|
Fragment:
val ->
quantity ->
nat ->
memval.
Encoding and decoding integers
We define functions to convert between integers and lists of bytes
of a given length
Fixpoint bytes_of_int (
n:
nat) (
x:
Z) {
struct n}:
list byte :=
match n with
|
O =>
nil
|
S m =>
Byte.repr x ::
bytes_of_int m (
x / 256)
end.
Fixpoint int_of_bytes (
l:
list byte):
Z :=
match l with
|
nil => 0
|
b ::
l' =>
Byte.unsigned b +
int_of_bytes l' * 256
end.
Definition rev_if_be (
l:
list byte) :
list byte :=
if Archi.big_endian then List.rev l else l.
Definition encode_int (
sz:
nat) (
x:
Z) :
list byte :=
rev_if_be (
bytes_of_int sz x).
Definition decode_int (
b:
list byte) :
Z :=
int_of_bytes (
rev_if_be b).
Length properties
Lemma length_bytes_of_int:
forall n x,
length (
bytes_of_int n x) =
n.
Proof.
induction n; simpl; intros. auto. decEq. auto.
Qed.
Lemma rev_if_be_length:
forall l,
length (
rev_if_be l) =
length l.
Proof.
Lemma encode_int_length:
forall sz x,
length(
encode_int sz x) =
sz.
Proof.
Decoding after encoding
Lemma int_of_bytes_of_int:
forall n x,
int_of_bytes (
bytes_of_int n x) =
x mod (
two_p (
Z.of_nat n * 8)).
Proof.
Lemma rev_if_be_involutive:
forall l,
rev_if_be (
rev_if_be l) =
l.
Proof.
Lemma decode_encode_int:
forall n x,
decode_int (
encode_int n x) =
x mod (
two_p (
Z.of_nat n * 8)).
Proof.
Lemma decode_encode_int_1:
forall x,
Int.repr (
decode_int (
encode_int 1 (
Int.unsigned x))) =
Int.zero_ext 8
x.
Proof.
Lemma decode_encode_int_2:
forall x,
Int.repr (
decode_int (
encode_int 2 (
Int.unsigned x))) =
Int.zero_ext 16
x.
Proof.
Lemma decode_encode_int_4:
forall x,
Int.repr (
decode_int (
encode_int 4 (
Int.unsigned x))) =
x.
Proof.
Lemma decode_encode_int_8:
forall x,
Int64.repr (
decode_int (
encode_int 8 (
Int64.unsigned x))) =
x.
Proof.
A length-n encoding depends only on the low 8*n bits of the integer.
Lemma bytes_of_int_mod:
forall n x y,
eqmod (
two_p (
Z.of_nat n * 8))
x y ->
bytes_of_int n x =
bytes_of_int n y.
Proof.
Lemma encode_int_8_mod:
forall x y,
eqmod (
two_p 8)
x y ->
encode_int 1%
nat x =
encode_int 1%
nat y.
Proof.
Lemma encode_int_16_mod:
forall x y,
eqmod (
two_p 16)
x y ->
encode_int 2%
nat x =
encode_int 2%
nat y.
Proof.
Encoding and decoding values
Definition inj_bytes (
bl:
list byte) :
list memval :=
List.map Byte bl.
Fixpoint proj_bytes (
vl:
list memval) :
option (
list byte) :=
match vl with
|
nil =>
Some nil
|
Byte b ::
vl' =>
match proj_bytes vl'
with None =>
None |
Some bl =>
Some(
b ::
bl)
end
|
_ =>
None
end.
Remark length_inj_bytes:
forall bl,
length (
inj_bytes bl) =
length bl.
Proof.
Remark proj_inj_bytes:
forall bl,
proj_bytes (
inj_bytes bl) =
Some bl.
Proof.
induction bl; simpl. auto. rewrite IHbl. auto.
Qed.
Lemma inj_proj_bytes:
forall cl bl,
proj_bytes cl =
Some bl ->
cl =
inj_bytes bl.
Proof.
induction cl;
simpl;
intros.
inv H;
auto.
destruct a;
try congruence.
destruct (
proj_bytes cl);
inv H.
simpl.
decEq.
auto.
Qed.
Fixpoint inj_value_rec (
n:
nat) (
v:
val) (
q:
quantity) {
struct n}:
list memval :=
match n with
|
O =>
nil
|
S m =>
Fragment v q m ::
inj_value_rec m v q
end.
Definition inj_value (
q:
quantity) (
v:
val):
list memval :=
inj_value_rec (
size_quantity_nat q)
v q.
Fixpoint check_value (
n:
nat) (
v:
val) (
q:
quantity) (
vl:
list memval)
{
struct n} :
bool :=
match n,
vl with
|
O,
nil =>
true
|
S m,
Fragment v'
q'
m' ::
vl' =>
Val.eq v v' &&
quantity_eq q q' &&
Nat.eqb m m' &&
check_value m v q vl'
|
_,
_ =>
false
end.
Definition proj_value (
q:
quantity) (
vl:
list memval) :
val :=
match vl with
|
Fragment v q'
n ::
vl' =>
if check_value (
size_quantity_nat q)
v q vl then v else Vundef
|
_ =>
Vundef
end.
Definition encode_val (
chunk:
memory_chunk) (
v:
val) :
list memval :=
match v,
chunk with
|
Vint n, (
Mint8signed |
Mint8unsigned) =>
inj_bytes (
encode_int 1%
nat (
Int.unsigned n))
|
Vint n, (
Mint16signed |
Mint16unsigned) =>
inj_bytes (
encode_int 2%
nat (
Int.unsigned n))
|
Vint n,
Mint32 =>
inj_bytes (
encode_int 4%
nat (
Int.unsigned n))
|
Vptr b ofs,
Mint32 =>
if Archi.ptr64 then List.repeat Undef 4%
nat else inj_value Q32 v
|
Vlong n,
Mint64 =>
inj_bytes (
encode_int 8%
nat (
Int64.unsigned n))
|
Vptr b ofs,
Mint64 =>
if Archi.ptr64 then inj_value Q64 v else List.repeat Undef 8%
nat
|
Vsingle n,
Mfloat32 =>
inj_bytes (
encode_int 4%
nat (
Int.unsigned (
Float32.to_bits n)))
|
Vfloat n,
Mfloat64 =>
inj_bytes (
encode_int 8%
nat (
Int64.unsigned (
Float.to_bits n)))
|
_,
Many32 =>
inj_value Q32 v
|
_,
Many64 =>
inj_value Q64 v
|
_,
_ =>
List.repeat Undef (
size_chunk_nat chunk)
end.
Definition decode_val (
chunk:
memory_chunk) (
vl:
list memval) :
val :=
match proj_bytes vl with
|
Some bl =>
match chunk with
|
Mint8signed =>
Vint(
Int.sign_ext 8 (
Int.repr (
decode_int bl)))
|
Mint8unsigned =>
Vint(
Int.zero_ext 8 (
Int.repr (
decode_int bl)))
|
Mint16signed =>
Vint(
Int.sign_ext 16 (
Int.repr (
decode_int bl)))
|
Mint16unsigned =>
Vint(
Int.zero_ext 16 (
Int.repr (
decode_int bl)))
|
Mint32 =>
Vint(
Int.repr(
decode_int bl))
|
Mint64 =>
Vlong(
Int64.repr(
decode_int bl))
|
Mfloat32 =>
Vsingle(
Float32.of_bits (
Int.repr (
decode_int bl)))
|
Mfloat64 =>
Vfloat(
Float.of_bits (
Int64.repr (
decode_int bl)))
|
Many32 =>
Vundef
|
Many64 =>
Vundef
end
|
None =>
match chunk with
|
Mint32 =>
if Archi.ptr64 then Vundef else Val.load_result chunk (
proj_value Q32 vl)
|
Many32 =>
Val.load_result chunk (
proj_value Q32 vl)
|
Mint64 =>
if Archi.ptr64 then Val.load_result chunk (
proj_value Q64 vl)
else Vundef
|
Many64 =>
Val.load_result chunk (
proj_value Q64 vl)
|
_ =>
Vundef
end
end.
Ltac solve_encode_val_length :=
match goal with
| [ |-
length (
inj_bytes _) =
_ ] =>
rewrite length_inj_bytes;
solve_encode_val_length
| [ |-
length (
encode_int _ _) =
_ ] =>
apply encode_int_length
| [ |-
length (
if ?
x then _ else _) =
_ ] =>
destruct x eqn:?;
solve_encode_val_length
|
_ =>
reflexivity
end.
Lemma encode_val_length:
forall chunk v,
length(
encode_val chunk v) =
size_chunk_nat chunk.
Proof.
intros. destruct v; simpl; destruct chunk; solve_encode_val_length.
Qed.
Lemma check_inj_value:
forall v q n,
check_value n v q (
inj_value_rec n v q) =
true.
Proof.
Lemma proj_inj_value:
forall q v,
proj_value q (
inj_value q v) =
v.
Proof.
Remark in_inj_value:
forall mv v q,
In mv (
inj_value q v) ->
exists n,
mv =
Fragment v q n.
Proof.
Local Transparent inj_value.
unfold inj_value;
intros until q.
generalize (
size_quantity_nat q).
induction n;
simpl;
intros.
contradiction.
destruct H.
exists n;
auto.
eauto.
Qed.
Lemma proj_inj_value_mismatch:
forall q1 q2 v,
q1 <>
q2 ->
proj_value q1 (
inj_value q2 v) =
Vundef.
Proof.
Definition decode_encode_val (
v1:
val) (
chunk1 chunk2:
memory_chunk) (
v2:
val) :
Prop :=
match v1,
chunk1,
chunk2 with
|
Vundef,
_,
_ =>
v2 =
Vundef
|
Vint n,
Mint8signed,
Mint8signed =>
v2 =
Vint(
Int.sign_ext 8
n)
|
Vint n,
Mint8unsigned,
Mint8signed =>
v2 =
Vint(
Int.sign_ext 8
n)
|
Vint n,
Mint8signed,
Mint8unsigned =>
v2 =
Vint(
Int.zero_ext 8
n)
|
Vint n,
Mint8unsigned,
Mint8unsigned =>
v2 =
Vint(
Int.zero_ext 8
n)
|
Vint n,
Mint16signed,
Mint16signed =>
v2 =
Vint(
Int.sign_ext 16
n)
|
Vint n,
Mint16unsigned,
Mint16signed =>
v2 =
Vint(
Int.sign_ext 16
n)
|
Vint n,
Mint16signed,
Mint16unsigned =>
v2 =
Vint(
Int.zero_ext 16
n)
|
Vint n,
Mint16unsigned,
Mint16unsigned =>
v2 =
Vint(
Int.zero_ext 16
n)
|
Vint n,
Mint32,
Mint32 =>
v2 =
Vint n
|
Vint n,
Many32,
Many32 =>
v2 =
Vint n
|
Vint n,
Mint32,
Mfloat32 =>
v2 =
Vsingle(
Float32.of_bits n)
|
Vint n,
Many64,
Many64 =>
v2 =
Vint n
|
Vint n, (
Mint64 |
Mfloat32 |
Mfloat64 |
Many64),
_ =>
v2 =
Vundef
|
Vint n,
_,
_ =>
True (* nothing meaningful to say about v2 *)
|
Vptr b ofs, (
Mint32 |
Many32), (
Mint32 |
Many32) =>
v2 =
if Archi.ptr64 then Vundef else Vptr b ofs
|
Vptr b ofs,
Mint64, (
Mint64 |
Many64) =>
v2 =
if Archi.ptr64 then Vptr b ofs else Vundef
|
Vptr b ofs,
Many64,
Many64 =>
v2 =
Vptr b ofs
|
Vptr b ofs,
Many64,
Mint64 =>
v2 =
if Archi.ptr64 then Vptr b ofs else Vundef
|
Vptr b ofs,
_,
_ =>
v2 =
Vundef
|
Vlong n,
Mint64,
Mint64 =>
v2 =
Vlong n
|
Vlong n,
Mint64,
Mfloat64 =>
v2 =
Vfloat(
Float.of_bits n)
|
Vlong n,
Many64,
Many64 =>
v2 =
Vlong n
|
Vlong n, (
Mint8signed|
Mint8unsigned|
Mint16signed|
Mint16unsigned|
Mint32|
Mfloat32|
Mfloat64|
Many32),
_ =>
v2 =
Vundef
|
Vlong n,
_,
_ =>
True (* nothing meaningful to say about v2 *)
|
Vfloat f,
Mfloat64,
Mfloat64 =>
v2 =
Vfloat f
|
Vfloat f,
Mfloat64,
Mint64 =>
v2 =
Vlong(
Float.to_bits f)
|
Vfloat f,
Many64,
Many64 =>
v2 =
Vfloat f
|
Vfloat f, (
Mint8signed|
Mint8unsigned|
Mint16signed|
Mint16unsigned|
Mint32|
Mfloat32|
Mint64|
Many32),
_ =>
v2 =
Vundef
|
Vfloat f,
_,
_ =>
True
|
Vsingle f,
Mfloat32,
Mfloat32 =>
v2 =
Vsingle f
|
Vsingle f,
Mfloat32,
Mint32 =>
v2 =
Vint(
Float32.to_bits f)
|
Vsingle f,
Many32,
Many32 =>
v2 =
Vsingle f
|
Vsingle f,
Many64,
Many64 =>
v2 =
Vsingle f
|
Vsingle f, (
Mint8signed|
Mint8unsigned|
Mint16signed|
Mint16unsigned|
Mint32|
Mint64|
Mfloat64|
Many64),
_ =>
v2 =
Vundef
|
Vsingle f,
_,
_ =>
True
end.
Remark decode_val_undef:
forall bl chunk,
decode_val chunk (
Undef ::
bl) =
Vundef.
Proof.
Remark proj_bytes_inj_value:
forall q v,
proj_bytes (
inj_value q v) =
None.
Proof.
intros. destruct q; reflexivity.
Qed.
Ltac solve_decode_encode_val_general :=
exact I ||
reflexivity ||
match goal with
| |-
context [
if Archi.ptr64 then _ else _ ] =>
destruct Archi.ptr64 eqn:?
| |-
context [
proj_bytes (
inj_bytes _) ] =>
rewrite proj_inj_bytes
| |-
context [
proj_bytes (
inj_value _ _) ] =>
rewrite proj_bytes_inj_value
| |-
context [
proj_value _ (
inj_value _ _) ] =>
rewrite ?
proj_inj_value, ?
proj_inj_value_mismatch by congruence
| |-
context [
Int.repr(
decode_int (
encode_int 1 (
Int.unsigned _))) ] =>
rewrite decode_encode_int_1
| |-
context [
Int.repr(
decode_int (
encode_int 2 (
Int.unsigned _))) ] =>
rewrite decode_encode_int_2
| |-
context [
Int.repr(
decode_int (
encode_int 4 (
Int.unsigned _))) ] =>
rewrite decode_encode_int_4
| |-
context [
Int64.repr(
decode_int (
encode_int 8 (
Int64.unsigned _))) ] =>
rewrite decode_encode_int_8
| |-
Vint (
Int.sign_ext _ (
Int.sign_ext _ _)) =
Vint _ =>
f_equal;
apply Int.sign_ext_idem;
lia
| |-
Vint (
Int.zero_ext _ (
Int.zero_ext _ _)) =
Vint _ =>
f_equal;
apply Int.zero_ext_idem;
lia
| |-
Vint (
Int.sign_ext _ (
Int.zero_ext _ _)) =
Vint _ =>
f_equal;
apply Int.sign_ext_zero_ext;
lia
end.
Lemma decode_encode_val_general:
forall v chunk1 chunk2,
decode_encode_val v chunk1 chunk2 (
decode_val chunk2 (
encode_val chunk1 v)).
Proof.
Lemma decode_encode_val_similar:
forall v1 chunk1 chunk2 v2,
type_of_chunk chunk1 =
type_of_chunk chunk2 ->
size_chunk chunk1 =
size_chunk chunk2 ->
decode_encode_val v1 chunk1 chunk2 v2 ->
v2 =
Val.load_result chunk2 v1.
Proof.
intros until v2; intros TY SZ DE.
destruct chunk1; destruct chunk2; simpl in TY; try discriminate; simpl in SZ; try extlia;
destruct v1; auto.
Qed.
Lemma decode_val_rettype:
forall chunk cl,
Val.has_rettype (
decode_val chunk cl) (
rettype_of_chunk chunk).
Proof.
Lemma decode_val_type:
forall chunk cl,
Val.has_type (
decode_val chunk cl) (
type_of_chunk chunk).
Proof.
Lemma encode_val_int8_signed_unsigned:
forall v,
encode_val Mint8signed v =
encode_val Mint8unsigned v.
Proof.
intros. destruct v; simpl; auto.
Qed.
Lemma encode_val_int16_signed_unsigned:
forall v,
encode_val Mint16signed v =
encode_val Mint16unsigned v.
Proof.
intros. destruct v; simpl; auto.
Qed.
Lemma encode_val_int8_zero_ext:
forall n,
encode_val Mint8unsigned (
Vint (
Int.zero_ext 8
n)) =
encode_val Mint8unsigned (
Vint n).
Proof.
Lemma encode_val_int8_sign_ext:
forall n,
encode_val Mint8signed (
Vint (
Int.sign_ext 8
n)) =
encode_val Mint8signed (
Vint n).
Proof.
Lemma encode_val_int16_zero_ext:
forall n,
encode_val Mint16unsigned (
Vint (
Int.zero_ext 16
n)) =
encode_val Mint16unsigned (
Vint n).
Proof.
Lemma encode_val_int16_sign_ext:
forall n,
encode_val Mint16signed (
Vint (
Int.sign_ext 16
n)) =
encode_val Mint16signed (
Vint n).
Proof.
Lemma decode_val_cast:
forall chunk l,
let v :=
decode_val chunk l in
match chunk with
|
Mint8signed =>
v =
Val.sign_ext 8
v
|
Mint8unsigned =>
v =
Val.zero_ext 8
v
|
Mint16signed =>
v =
Val.sign_ext 16
v
|
Mint16unsigned =>
v =
Val.zero_ext 16
v
|
_ =>
True
end.
Proof.
Pointers cannot be forged.
Definition quantity_chunk (
chunk:
memory_chunk) :=
match chunk with
|
Mint64 |
Mfloat64 |
Many64 =>
Q64
|
_ =>
Q32
end.
Inductive shape_encoding (
chunk:
memory_chunk) (
v:
val):
list memval ->
Prop :=
|
shape_encoding_f:
forall q i mvl,
(
chunk =
Mint32 \/
chunk =
Many32 \/
chunk =
Mint64 \/
chunk =
Many64) ->
q =
quantity_chunk chunk ->
S i =
size_quantity_nat q ->
(
forall mv,
In mv mvl ->
exists j,
mv =
Fragment v q j /\
S j <>
size_quantity_nat q) ->
shape_encoding chunk v (
Fragment v q i ::
mvl)
|
shape_encoding_b:
forall b mvl,
match v with Vint _ =>
True |
Vlong _ =>
True |
Vfloat _ =>
True |
Vsingle _ =>
True |
_ =>
False end ->
(
forall mv,
In mv mvl ->
exists b',
mv =
Byte b') ->
shape_encoding chunk v (
Byte b ::
mvl)
|
shape_encoding_u:
forall mvl,
(
forall mv,
In mv mvl ->
mv =
Undef) ->
shape_encoding chunk v (
Undef ::
mvl).
Lemma encode_val_shape:
forall chunk v,
shape_encoding chunk v (
encode_val chunk v).
Proof.
Inductive shape_decoding (
chunk:
memory_chunk):
list memval ->
val ->
Prop :=
|
shape_decoding_f:
forall v q i mvl,
(
chunk =
Mint32 \/
chunk =
Many32 \/
chunk =
Mint64 \/
chunk =
Many64) ->
q =
quantity_chunk chunk ->
S i =
size_quantity_nat q ->
(
forall mv,
In mv mvl ->
exists j,
mv =
Fragment v q j /\
S j <>
size_quantity_nat q) ->
shape_decoding chunk (
Fragment v q i ::
mvl) (
Val.load_result chunk v)
|
shape_decoding_b:
forall b mvl v,
match v with Vint _ =>
True |
Vlong _ =>
True |
Vfloat _ =>
True |
Vsingle _ =>
True |
_ =>
False end ->
(
forall mv,
In mv mvl ->
exists b',
mv =
Byte b') ->
shape_decoding chunk (
Byte b ::
mvl)
v
|
shape_decoding_u:
forall mvl,
shape_decoding chunk mvl Vundef.
Lemma decode_val_shape:
forall chunk mv1 mvl,
shape_decoding chunk (
mv1 ::
mvl) (
decode_val chunk (
mv1 ::
mvl)).
Proof.
Compatibility with memory injections
Relating two memory values according to a memory injection.
Inductive memval_inject (
f:
meminj):
memval ->
memval ->
Prop :=
|
memval_inject_byte:
forall n,
memval_inject f (
Byte n) (
Byte n)
|
memval_inject_frag:
forall v1 v2 q n,
Val.inject f v1 v2 ->
memval_inject f (
Fragment v1 q n) (
Fragment v2 q n)
|
memval_inject_undef:
forall mv,
memval_inject f Undef mv.
Lemma memval_inject_incr:
forall f f'
v1 v2,
memval_inject f v1 v2 ->
inject_incr f f' ->
memval_inject f'
v1 v2.
Proof.
decode_val, applied to lists of memory values that are pairwise
related by memval_inject, returns values that are related by Val.inject.
Lemma proj_bytes_inject:
forall f vl vl',
list_forall2 (
memval_inject f)
vl vl' ->
forall bl,
proj_bytes vl =
Some bl ->
proj_bytes vl' =
Some bl.
Proof.
induction 1;
simpl.
congruence.
inv H;
try congruence.
destruct (
proj_bytes al);
intros.
inv H.
rewrite (
IHlist_forall2 l);
auto.
congruence.
Qed.
Lemma check_value_inject:
forall f vl vl',
list_forall2 (
memval_inject f)
vl vl' ->
forall v v'
q n,
check_value n v q vl =
true ->
Val.inject f v v' ->
v <>
Vundef ->
check_value n v'
q vl' =
true.
Proof.
induction 1;
intros;
destruct n;
simpl in *;
auto.
inv H;
auto.
InvBooleans.
assert (
n =
n0)
by (
apply Nat.eqb_eq;
auto).
subst v1 q0 n0.
replace v2 with v'.
unfold proj_sumbool;
rewrite !
dec_eq_true.
rewrite Nat.eqb_refl.
simpl;
eauto.
inv H2;
try discriminate;
inv H4;
congruence.
discriminate.
Qed.
Lemma proj_value_inject:
forall f q vl1 vl2,
list_forall2 (
memval_inject f)
vl1 vl2 ->
Val.inject f (
proj_value q vl1) (
proj_value q vl2).
Proof.
Lemma proj_bytes_not_inject:
forall f vl vl',
list_forall2 (
memval_inject f)
vl vl' ->
proj_bytes vl =
None ->
proj_bytes vl' <>
None ->
In Undef vl.
Proof.
induction 1;
simpl;
intros.
congruence.
inv H;
try congruence.
right.
apply IHlist_forall2.
destruct (
proj_bytes al);
congruence.
destruct (
proj_bytes bl);
congruence.
auto.
Qed.
Lemma check_value_undef:
forall n q v vl,
In Undef vl ->
check_value n v q vl =
false.
Proof.
induction n;
intros;
simpl.
destruct vl.
elim H.
auto.
destruct vl.
auto.
destruct m;
auto.
simpl in H;
destruct H.
congruence.
rewrite IHn;
auto.
apply andb_false_r.
Qed.
Lemma proj_value_undef:
forall q vl,
In Undef vl ->
proj_value q vl =
Vundef.
Proof.
Theorem decode_val_inject:
forall f vl1 vl2 chunk,
list_forall2 (
memval_inject f)
vl1 vl2 ->
Val.inject f (
decode_val chunk vl1) (
decode_val chunk vl2).
Proof.
Symmetrically, encode_val, applied to values related by Val.inject,
returns lists of memory values that are pairwise
related by memval_inject.
Lemma inj_bytes_inject:
forall f bl,
list_forall2 (
memval_inject f) (
inj_bytes bl) (
inj_bytes bl).
Proof.
induction bl; constructor; auto. constructor.
Qed.
Lemma repeat_Undef_inject_any:
forall f vl,
list_forall2 (
memval_inject f) (
List.repeat Undef (
length vl))
vl.
Proof.
induction vl; simpl; constructor; auto. constructor.
Qed.
Lemma repeat_Undef_inject_encode_val:
forall f chunk v,
list_forall2 (
memval_inject f) (
List.repeat Undef (
size_chunk_nat chunk)) (
encode_val chunk v).
Proof.
Lemma repeat_Undef_inject_self:
forall f n,
list_forall2 (
memval_inject f) (
List.repeat Undef n) (
List.repeat Undef n).
Proof.
induction n; simpl; constructor; auto. constructor.
Qed.
Lemma inj_value_inject:
forall f v1 v2 q,
Val.inject f v1 v2 ->
list_forall2 (
memval_inject f) (
inj_value q v1) (
inj_value q v2).
Proof.
Theorem encode_val_inject:
forall f v1 v2 chunk,
Val.inject f v1 v2 ->
list_forall2 (
memval_inject f) (
encode_val chunk v1) (
encode_val chunk v2).
Proof.
Definition memval_lessdef:
memval ->
memval ->
Prop :=
memval_inject inject_id.
Lemma memval_lessdef_refl:
forall mv,
memval_lessdef mv mv.
Proof.
memval_inject and compositions
Lemma memval_inject_compose:
forall f f'
v1 v2 v3,
memval_inject f v1 v2 ->
memval_inject f'
v2 v3 ->
memval_inject (
compose_meminj f f')
v1 v3.
Proof.
intros.
inv H.
inv H0.
constructor.
inv H0.
econstructor.
eapply val_inject_compose;
eauto.
constructor.
Qed.
Breaking 64-bit memory accesses into two 32-bit accesses
Lemma int_of_bytes_append:
forall l2 l1,
int_of_bytes (
l1 ++
l2) =
int_of_bytes l1 +
int_of_bytes l2 *
two_p (
Z.of_nat (
length l1) * 8).
Proof.
Lemma int_of_bytes_range:
forall l, 0 <=
int_of_bytes l <
two_p (
Z.of_nat (
length l) * 8).
Proof.
Lemma length_proj_bytes:
forall l b,
proj_bytes l =
Some b ->
length b =
length l.
Proof.
induction l;
simpl;
intros.
inv H;
auto.
destruct a;
try discriminate.
destruct (
proj_bytes l)
eqn:
E;
inv H.
simpl.
f_equal.
auto.
Qed.
Lemma proj_bytes_append:
forall l2 l1,
proj_bytes (
l1 ++
l2) =
match proj_bytes l1,
proj_bytes l2 with
|
Some b1,
Some b2 =>
Some (
b1 ++
b2)
|
_,
_ =>
None
end.
Proof.
induction l1;
simpl.
destruct (
proj_bytes l2);
auto.
destruct a;
auto.
rewrite IHl1.
destruct (
proj_bytes l1);
auto.
destruct (
proj_bytes l2);
auto.
Qed.
Lemma decode_val_int64:
forall l1 l2,
length l1 = 4%
nat ->
length l2 = 4%
nat ->
Archi.ptr64 =
false ->
Val.lessdef
(
decode_val Mint64 (
l1 ++
l2))
(
Val.longofwords (
decode_val Mint32 (
if Archi.big_endian then l1 else l2))
(
decode_val Mint32 (
if Archi.big_endian then l2 else l1))).
Proof.
Lemma bytes_of_int_append:
forall n2 x2 n1 x1,
0 <=
x1 <
two_p (
Z.of_nat n1 * 8) ->
bytes_of_int (
n1 +
n2) (
x1 +
x2 *
two_p (
Z.of_nat n1 * 8)) =
bytes_of_int n1 x1 ++
bytes_of_int n2 x2.
Proof.
Lemma bytes_of_int64:
forall i,
bytes_of_int 8 (
Int64.unsigned i) =
bytes_of_int 4 (
Int.unsigned (
Int64.loword i)) ++
bytes_of_int 4 (
Int.unsigned (
Int64.hiword i)).
Proof.
Lemma encode_val_int64:
forall v,
Archi.ptr64 =
false ->
encode_val Mint64 v =
encode_val Mint32 (
if Archi.big_endian then Val.hiword v else Val.loword v)
++
encode_val Mint32 (
if Archi.big_endian then Val.loword v else Val.hiword v).
Proof.