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cpdt
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40f0d583
Commit
40f0d583
authored
Sep 03, 2008
by
Adam Chlipala
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Typed target denotation
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40f0d583
...
@@ -96,9 +96,17 @@ Fixpoint expDenote (e : exp) : nat :=
...
@@ -96,9 +96,17 @@ Fixpoint expDenote (e : exp) : nat :=
(
**
It
is
convenient
to
be
able
to
test
definitions
before
starting
to
prove
things
about
them
.
We
can
verify
that
our
semantics
is
sensible
by
evaluating
some
sample
uses
.
*
)
(
**
It
is
convenient
to
be
able
to
test
definitions
before
starting
to
prove
things
about
them
.
We
can
verify
that
our
semantics
is
sensible
by
evaluating
some
sample
uses
.
*
)
Eval
simpl
in
expDenote
(
Const
42
)
.
Eval
simpl
in
expDenote
(
Const
42
)
.
(
**
[[
=
42
:
nat
]]
*
)
Eval
simpl
in
expDenote
(
Binop
Plus
(
Const
2
)
(
Const
2
))
.
Eval
simpl
in
expDenote
(
Binop
Plus
(
Const
2
)
(
Const
2
))
.
(
**
[[
=
4
:
nat
]]
*
)
Eval
simpl
in
expDenote
(
Binop
Times
(
Binop
Plus
(
Const
2
)
(
Const
2
))
(
Const
7
))
.
Eval
simpl
in
expDenote
(
Binop
Times
(
Binop
Plus
(
Const
2
)
(
Const
2
))
(
Const
7
))
.
(
**
[[
=
28
:
nat
]]
*
)
(
**
**
Target
language
*
)
(
**
**
Target
language
*
)
...
@@ -154,14 +162,32 @@ Fixpoint compile (e : exp) : prog :=
...
@@ -154,14 +162,32 @@ Fixpoint compile (e : exp) : prog :=
(
**
Before
we
set
about
proving
that
this
compiler
is
correct
,
we
can
try
a
few
test
runs
,
using
our
sample
programs
from
earlier
.
*
)
(
**
Before
we
set
about
proving
that
this
compiler
is
correct
,
we
can
try
a
few
test
runs
,
using
our
sample
programs
from
earlier
.
*
)
Eval
simpl
in
compile
(
Const
42
)
.
Eval
simpl
in
compile
(
Const
42
)
.
(
**
[[
=
IConst
42
::
nil
:
prog
]]
*
)
Eval
simpl
in
compile
(
Binop
Plus
(
Const
2
)
(
Const
2
))
.
Eval
simpl
in
compile
(
Binop
Plus
(
Const
2
)
(
Const
2
))
.
(
**
[[
=
IConst
2
::
IConst
2
::
IBinop
Plus
::
nil
:
prog
]]
*
)
Eval
simpl
in
compile
(
Binop
Times
(
Binop
Plus
(
Const
2
)
(
Const
2
))
(
Const
7
))
.
Eval
simpl
in
compile
(
Binop
Times
(
Binop
Plus
(
Const
2
)
(
Const
2
))
(
Const
7
))
.
(
**
[[
=
IConst
7
::
IConst
2
::
IConst
2
::
IBinop
Plus
::
IBinop
Times
::
nil
:
prog
]]
*
)
(
**
We
can
also
run
our
compiled
programs
and
chedk
that
they
give
the
right
results
.
*
)
(
**
We
can
also
run
our
compiled
programs
and
chedk
that
they
give
the
right
results
.
*
)
Eval
simpl
in
progDenote
(
compile
(
Const
42
))
nil
.
Eval
simpl
in
progDenote
(
compile
(
Const
42
))
nil
.
(
**
[[
=
Some
(
42
::
nil
)
:
option
stack
]]
*
)
Eval
simpl
in
progDenote
(
compile
(
Binop
Plus
(
Const
2
)
(
Const
2
)))
nil
.
Eval
simpl
in
progDenote
(
compile
(
Binop
Plus
(
Const
2
)
(
Const
2
)))
nil
.
(
**
[[
=
Some
(
4
::
nil
)
:
option
stack
]]
*
)
Eval
simpl
in
progDenote
(
compile
(
Binop
Times
(
Binop
Plus
(
Const
2
)
(
Const
2
))
(
Const
7
)))
nil
.
Eval
simpl
in
progDenote
(
compile
(
Binop
Times
(
Binop
Plus
(
Const
2
)
(
Const
2
))
(
Const
7
)))
nil
.
(
**
[[
=
Some
(
28
::
nil
)
:
option
stack
]]
*
)
(
**
**
Translation
correctness
*
)
(
**
**
Translation
correctness
*
)
...
@@ -584,16 +610,41 @@ Fixpoint texpDenote t (e : texp t) {struct e} : typeDenote t :=
...
@@ -584,16 +610,41 @@ Fixpoint texpDenote t (e : texp t) {struct e} : typeDenote t :=
(
**
We
can
evaluate
a
few
example
programs
to
convince
ourselves
that
this
semantics
is
correct
.
*
)
(
**
We
can
evaluate
a
few
example
programs
to
convince
ourselves
that
this
semantics
is
correct
.
*
)
Eval
simpl
in
texpDenote
(
TNConst
42
)
.
Eval
simpl
in
texpDenote
(
TNConst
42
)
.
(
**
[[
=
42
:
typeDenote
Nat
]]
*
)
Eval
simpl
in
texpDenote
(
TBConst
true
)
.
Eval
simpl
in
texpDenote
(
TBConst
true
)
.
(
**
[[
=
true
:
typeDenote
Bool
]]
*
)
Eval
simpl
in
texpDenote
(
TBinop
TTimes
(
TBinop
TPlus
(
TNConst
2
)
(
TNConst
2
))
(
TNConst
7
))
.
Eval
simpl
in
texpDenote
(
TBinop
TTimes
(
TBinop
TPlus
(
TNConst
2
)
(
TNConst
2
))
(
TNConst
7
))
.
(
**
[[
=
28
:
typeDenote
Nat
]]
*
)
Eval
simpl
in
texpDenote
(
TBinop
(
TEq
Nat
)
(
TBinop
TPlus
(
TNConst
2
)
(
TNConst
2
))
(
TNConst
7
))
.
Eval
simpl
in
texpDenote
(
TBinop
(
TEq
Nat
)
(
TBinop
TPlus
(
TNConst
2
)
(
TNConst
2
))
(
TNConst
7
))
.
(
**
[[
=
false
:
typeDenote
Bool
]]
*
)
Eval
simpl
in
texpDenote
(
TBinop
TLt
(
TBinop
TPlus
(
TNConst
2
)
(
TNConst
2
))
(
TNConst
7
))
.
Eval
simpl
in
texpDenote
(
TBinop
TLt
(
TBinop
TPlus
(
TNConst
2
)
(
TNConst
2
))
(
TNConst
7
))
.
(
**
[[
=
true
:
typeDenote
Bool
]]
*
)
(
**
**
Target
language
*
)
(
**
**
Target
language
*
)
(
**
Now
we
want
to
define
a
suitable
stack
machine
target
for
compilation
.
In
the
example
of
the
untyped
language
,
stack
machine
programs
could
encounter
stack
underflows
and
"get stuck."
This
was
unfortunate
,
since
we
had
to
deal
with
this
complication
even
though
we
proved
that
our
compiler
never
produced
underflowing
programs
.
We
could
have
used
dependent
types
to
force
all
stack
machine
programs
to
be
underflow
-
free
.
For
our
new
languages
,
besides
underflow
,
we
also
have
the
problem
of
stack
slots
with
naturals
instead
of
bools
or
vice
versa
.
This
time
,
we
will
use
indexed
typed
families
to
avoid
the
need
to
reason
about
potential
failures
.
We
start
by
defining
stack
types
,
which
classify
sets
of
possible
stacks
.
*
)
Definition
tstack
:=
list
type
.
Definition
tstack
:=
list
type
.
(
**
Any
stack
classified
by
a
[
tstack
]
must
have
exactly
as
many
elements
,
and
each
stack
element
must
have
the
type
found
in
the
same
position
of
the
stack
type
.
We
can
define
instructions
in
terms
of
stack
types
,
where
every
instruction
'
s
type
tells
us
what
initial
stack
type
it
expects
and
what
final
stack
type
it
will
produce
.
*
)
Inductive
tinstr
:
tstack
->
tstack
->
Set
:=
Inductive
tinstr
:
tstack
->
tstack
->
Set
:=
|
TINConst
:
forall
s
,
nat
->
tinstr
s
(
Nat
::
s
)
|
TINConst
:
forall
s
,
nat
->
tinstr
s
(
Nat
::
s
)
|
TIBConst
:
forall
s
,
bool
->
tinstr
s
(
Bool
::
s
)
|
TIBConst
:
forall
s
,
bool
->
tinstr
s
(
Bool
::
s
)
...
@@ -601,6 +652,8 @@ Inductive tinstr : tstack -> tstack -> Set :=
...
@@ -601,6 +652,8 @@ Inductive tinstr : tstack -> tstack -> Set :=
tbinop
arg1
arg2
res
tbinop
arg1
arg2
res
->
tinstr
(
arg1
::
arg2
::
s
)
(
res
::
s
)
.
->
tinstr
(
arg1
::
arg2
::
s
)
(
res
::
s
)
.
(
**
Stack
machine
programs
must
be
a
similar
inductive
family
,
since
,
if
we
again
used
the
[
list
]
type
family
,
we
would
not
be
able
to
guarantee
that
intermediate
stack
types
match
within
a
program
.
*
)
Inductive
tprog
:
tstack
->
tstack
->
Set
:=
Inductive
tprog
:
tstack
->
tstack
->
Set
:=
|
TNil
:
forall
s
,
tprog
s
s
|
TNil
:
forall
s
,
tprog
s
s
|
TCons
:
forall
s1
s2
s3
,
|
TCons
:
forall
s1
s2
s3
,
...
@@ -608,12 +661,18 @@ Inductive tprog : tstack -> tstack -> Set :=
...
@@ -608,12 +661,18 @@ Inductive tprog : tstack -> tstack -> Set :=
->
tprog
s2
s3
->
tprog
s2
s3
->
tprog
s1
s3
.
->
tprog
s1
s3
.
(
**
Now
,
to
define
the
semantics
of
our
new
target
language
,
we
need
a
representation
for
stacks
at
runtime
.
We
will
again
take
advantage
of
type
information
to
define
types
of
value
stacks
that
,
by
construction
,
contain
the
right
number
and
types
of
elements
.
*
)
Fixpoint
vstack
(
ts
:
tstack
)
:
Set
:=
Fixpoint
vstack
(
ts
:
tstack
)
:
Set
:=
match
ts
with
match
ts
with
|
nil
=>
unit
|
nil
=>
unit
|
t
::
ts
'
=>
typeDenote
t
*
vstack
ts
'
|
t
::
ts
'
=>
typeDenote
t
*
vstack
ts
'
end
%
type
.
end
%
type
.
(
**
This
is
another
[
Set
]
-
valued
function
.
This
time
it
is
recursive
,
which
is
perfectly
valid
,
since
[
Set
]
is
not
treated
specially
in
determining
which
functions
may
be
written
.
We
say
that
the
value
stack
of
an
empty
stack
type
is
any
value
of
type
[
unit
]
,
which
has
just
a
single
value
,
[
tt
]
.
A
nonempty
stack
type
leads
to
a
value
stack
that
is
a
pair
,
whose
first
element
has
the
proper
type
and
whose
second
element
follows
the
representation
for
the
remainder
of
the
stack
type
.
This
idea
of
programming
with
types
can
take
a
while
to
internalize
,
but
it
enables
a
very
simple
definition
of
instruction
denotation
.
We
have
the
same
kind
of
type
annotations
for
the
dependent
[
match
]
,
but
everything
else
is
like
what
you
might
expect
from
a
Lisp
-
like
version
of
ML
that
ignored
type
information
.
Nonetheless
,
the
fact
that
[
tinstrDenote
]
passes
the
type
-
checker
guarantees
that
our
stack
machine
programs
can
never
go
wrong
.
*
)
Definition
tinstrDenote
ts
ts
'
(
i
:
tinstr
ts
ts
'
)
:
vstack
ts
->
vstack
ts
'
:=
Definition
tinstrDenote
ts
ts
'
(
i
:
tinstr
ts
ts
'
)
:
vstack
ts
->
vstack
ts
'
:=
match
i
in
(
tinstr
ts
ts
'
)
return
(
vstack
ts
->
vstack
ts
'
)
with
match
i
in
(
tinstr
ts
ts
'
)
return
(
vstack
ts
->
vstack
ts
'
)
with
|
TINConst
_
n
=>
fun
s
=>
(
n
,
s
)
|
TINConst
_
n
=>
fun
s
=>
(
n
,
s
)
...
@@ -624,6 +683,34 @@ Definition tinstrDenote ts ts' (i : tinstr ts ts') : vstack ts -> vstack ts' :=
...
@@ -624,6 +683,34 @@ Definition tinstrDenote ts ts' (i : tinstr ts ts') : vstack ts -> vstack ts' :=
end
end
end
.
end
.
(
**
Why
do
we
choose
to
use
an
anonymous
function
to
bind
the
initial
stack
in
every
case
of
the
[
match
]
?
Consider
this
well
-
intentioned
but
invalid
alternative
version
:
[[
Definition
tinstrDenote
ts
ts
'
(
i
:
tinstr
ts
ts
'
)
(
s
:
vstack
ts
)
:
vstack
ts
'
:=
match
i
in
(
tinstr
ts
ts
'
)
return
(
vstack
ts
'
)
with
|
TINConst
_
n
=>
(
n
,
s
)
|
TIBConst
_
b
=>
(
b
,
s
)
|
TIBinop
_
_
_
_
b
=>
match
s
with
(
arg1
,
(
arg2
,
s
'
))
=>
((
tbinopDenote
b
)
arg1
arg2
,
s
'
)
end
end
.
The
Coq
type
-
checker
complains
that
:
[[
The
term
"(n, s)"
has
type
"(nat * vstack ts)%type"
while
it
is
expected
to
have
type
"vstack (Nat :: t)"
]]
Recall
from
our
earlier
discussion
of
[
match
]
annotations
that
we
write
the
annotations
to
express
to
the
type
-
checker
the
relationship
between
the
type
indices
of
the
case
object
and
the
result
type
of
the
[
match
]
.
Coq
chooses
to
assign
to
the
wildcard
[
_
]
after
[
TINConst
]
the
name
[
t
]
,
and
the
type
error
is
telling
us
that
the
type
checker
cannot
prove
that
[
t
]
is
the
same
as
[
ts
]
.
By
moving
[
s
]
out
of
the
[
match
]
,
we
lose
the
ability
to
express
,
with
[
in
]
and
[
return
]
clauses
,
the
relationship
between
the
shared
index
[
ts
]
of
[
s
]
and
[
i
]
.
There
%
\
textit
{%
#
<
i
>
#
are
#
</
i
>
#
%}%
reasonably
general
ways
of
getting
around
this
problem
without
pushing
binders
inside
[
match
]
es
.
However
,
the
alternatives
are
significantly
more
involved
,
and
the
technique
we
use
here
is
almost
certainly
the
best
choice
,
whenever
it
applies
.
*
)
(
**
We
finish
the
semantics
with
a
straightforward
definition
of
program
denotation
.
*
)
Fixpoint
tprogDenote
ts
ts
'
(
p
:
tprog
ts
ts
'
)
{
struct
p
}
:
vstack
ts
->
vstack
ts
'
:=
Fixpoint
tprogDenote
ts
ts
'
(
p
:
tprog
ts
ts
'
)
{
struct
p
}
:
vstack
ts
->
vstack
ts
'
:=
match
p
in
(
tprog
ts
ts
'
)
return
(
vstack
ts
->
vstack
ts
'
)
with
match
p
in
(
tprog
ts
ts
'
)
return
(
vstack
ts
->
vstack
ts
'
)
with
|
TNil
_
=>
fun
s
=>
s
|
TNil
_
=>
fun
s
=>
s
...
...
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