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14076b2b
Commit
14076b2b
authored
Feb 05, 2013
by
Adam Chlipala
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Plain Diff
Pass through Chapter 10
parent
bc87c0b3
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14076b2b
...
...
@@ -244,7 +244,7 @@ Section fhlist_map.
(
*
end
thide
*
)
(
*
end
hide
*
)
(
**
For
the
inductive
versions
of
the
[
ilist
]
definitions
,
we
proved
a
lemma
about
the
interaction
of
[
get
]
and
[
imap
]
.
It
was
a
strategic
choice
not
to
attempt
such
a
proof
for
the
definitions
that
we
just
gave
,
because
that
sets
us
on
a
collision
course
with
the
problems
that
are
the
subject
of
this
chapter
.
*
)
(
**
For
the
inductive
versions
of
the
[
ilist
]
definitions
,
we
proved
a
lemma
about
the
interaction
of
[
get
]
and
[
imap
]
.
It
was
a
strategic
choice
not
to
attempt
such
a
proof
for
the
definitions
that
we
just
gave
,
which
sets
us
on
a
collision
course
with
the
problems
that
are
the
subject
of
this
chapter
.
*
)
Variable
elm
:
A
.
...
...
@@ -270,7 +270,7 @@ Section fhlist_map.
end
]]
This
seems
like
a
trivial
enough
obligation
.
The
equality
proof
[
a0
]
must
be
[
eq_refl
]
,
since
that
is
the
only
constructor
of
[
eq
]
.
Therefore
,
both
the
[
match
]
es
reduce
to
the
point
where
the
conclusion
follows
by
reflexivity
.
This
seems
like
a
trivial
enough
obligation
.
The
equality
proof
[
a0
]
must
be
[
eq_refl
]
,
the
only
constructor
of
[
eq
]
.
Therefore
,
both
the
[
match
]
es
reduce
to
the
point
where
the
conclusion
follows
by
reflexivity
.
[[
destruct
a0
.
]]
...
...
@@ -279,7 +279,7 @@ Section fhlist_map.
User
error
:
Cannot
solve
a
second
-
order
unification
problem
>>
This
is
one
of
Coq
'
s
standard
error
messages
for
informing
us
that
its
heuristics
for
attempting
an
instance
of
an
undecidable
problem
about
dependent
typing
have
failed
.
We
might
try
to
nudge
things
in
the
right
direction
by
stating
the
lemma
that
we
believe
makes
the
conclusion
trivial
.
This
is
one
of
Coq
'
s
standard
error
messages
for
informing
us
of
a
failure
in
its
heuristics
for
attempting
an
instance
of
an
undecidable
problem
about
dependent
typing
.
We
might
try
to
nudge
things
in
the
right
direction
by
stating
the
lemma
that
we
believe
makes
the
conclusion
trivial
.
[[
assert
(
a0
=
eq_refl
_
)
.
]]
...
...
@@ -432,7 +432,7 @@ forall (U : Type) (p : U) (Q : U -> Type) (x : Q p) (h : p = p),
x
=
eq_rect
p
Q
x
p
h
]
]]
The
axiom
%
\
index
{
Gallina
terms
!
eq
\
_
rect
\
_
eq
}%
[
eq_rect_eq
]
states
a
"fact"
that
seems
like
common
sense
,
once
the
notation
is
deciphered
.
The
term
[
eq_rect
]
is
the
automatically
generated
recursion
principle
for
[
eq
]
.
Calling
[
eq_rect
]
is
another
way
of
[
match
]
ing
on
an
equality
proof
.
The
proof
we
match
on
is
the
argument
[
h
]
,
and
[
x
]
is
the
body
of
the
[
match
]
.
The
statement
of
[
eq_rect_eq
]
just
says
that
[
match
]
es
on
proofs
of
[
p
=
p
]
,
for
any
[
p
]
,
are
superfluous
and
may
be
removed
.
We
can
see
this
intuition
better
in
code
by
asking
Coq
to
simplify
the
theorem
statement
with
the
[
compute
]
reduction
strategy
(
which
,
by
the
way
,
applies
all
applicable
rules
of
the
definitional
equality
presented
in
this
chapter
'
s
first
section
)
.
*
)
The
axiom
%
\
index
{
Gallina
terms
!
eq
\
_
rect
\
_
eq
}%
[
eq_rect_eq
]
states
a
"fact"
that
seems
like
common
sense
,
once
the
notation
is
deciphered
.
The
term
[
eq_rect
]
is
the
automatically
generated
recursion
principle
for
[
eq
]
.
Calling
[
eq_rect
]
is
another
way
of
[
match
]
ing
on
an
equality
proof
.
The
proof
we
match
on
is
the
argument
[
h
]
,
and
[
x
]
is
the
body
of
the
[
match
]
.
The
statement
of
[
eq_rect_eq
]
just
says
that
[
match
]
es
on
proofs
of
[
p
=
p
]
,
for
any
[
p
]
,
are
superfluous
and
may
be
removed
.
We
can
see
this
intuition
better
in
code
by
asking
Coq
to
simplify
the
theorem
statement
with
the
[
compute
]
reduction
strategy
.
*
)
(
*
begin
hide
*
)
(
*
begin
thide
*
)
...
...
@@ -628,7 +628,7 @@ The term "pf" has type "a :: (ls1 ++ ls2) ++ ls3 = a :: ls1 ++ ls2 ++ ls3"
end
]]
The
conclusion
has
gotten
markedly
simpler
.
It
seems
counterintuitive
that
we
can
have
an
easier
time
of
proving
a
more
general
theorem
,
but
that
is
exactly
the
case
here
and
for
many
other
proofs
that
use
dependent
types
heavily
.
Speaking
informally
,
the
reason
why
this
kind
of
activity
helps
is
that
[
match
]
annotations
contain
some
positions
where
only
variables
are
allowed
.
By
reducing
more
elements
of
a
goal
to
variables
,
built
-
in
tactics
can
have
more
success
building
[
match
]
terms
under
the
hood
.
The
conclusion
has
gotten
markedly
simpler
.
It
seems
counterintuitive
that
we
can
have
an
easier
time
of
proving
a
more
general
theorem
,
but
such
a
phenomenon
applies
to
the
case
here
and
to
many
other
proofs
that
use
dependent
types
heavily
.
Speaking
informally
,
the
reason
why
this
kind
of
activity
helps
is
that
[
match
]
annotations
contain
some
positions
where
only
variables
are
allowed
.
By
reducing
more
elements
of
a
goal
to
variables
,
built
-
in
tactics
can
have
more
success
building
[
match
]
terms
under
the
hood
.
In
this
case
,
it
is
helpful
to
generalize
over
our
two
proofs
as
well
.
*
)
...
...
@@ -646,7 +646,7 @@ The term "pf" has type "a :: (ls1 ++ ls2) ++ ls3 = a :: ls1 ++ ls2 ++ ls3"
end
]]
To
an
experienced
dependent
types
hacker
,
the
appearance
of
this
goal
term
calls
for
a
celebration
.
The
formula
has
a
critical
property
that
indicates
that
our
problems
are
over
.
To
get
our
proofs
into
the
right
form
to
apply
[
UIP_refl
]
,
we
need
to
use
associativity
of
list
append
to
rewrite
their
types
.
We
could
not
do
that
before
because
other
parts
of
the
goal
require
the
proofs
to
retain
their
original
types
.
In
particular
,
the
call
to
[
fhapp
]
that
we
generalized
must
have
type
[(
ls1
++
ls2
)
++
ls3
]
,
for
some
values
of
the
list
variables
.
If
we
rewrite
the
type
of
the
proof
used
to
type
-
cast
this
value
to
something
like
[
ls1
++
ls2
++
ls3
=
ls1
++
ls2
++
ls3
]
,
then
the
lefthand
side
of
the
equality
would
no
longer
match
the
type
of
the
term
we
are
trying
to
cast
.
To
an
experienced
dependent
types
hacker
,
the
appearance
of
this
goal
term
calls
for
a
celebration
.
The
formula
has
a
critical
property
that
indicates
that
our
problems
are
over
.
To
get
our
proofs
into
the
right
form
to
apply
[
UIP_refl
]
,
we
need
to
use
associativity
of
list
append
to
rewrite
their
types
.
We
could
not
do
so
before
because
other
parts
of
the
goal
require
the
proofs
to
retain
their
original
types
.
In
particular
,
the
call
to
[
fhapp
]
that
we
generalized
must
have
type
[(
ls1
++
ls2
)
++
ls3
]
,
for
some
values
of
the
list
variables
.
If
we
rewrite
the
type
of
the
proof
used
to
type
-
cast
this
value
to
something
like
[
ls1
++
ls2
++
ls3
=
ls1
++
ls2
++
ls3
]
,
then
the
lefthand
side
of
the
equality
would
no
longer
match
the
type
of
the
term
we
are
trying
to
cast
.
However
,
now
that
we
have
generalized
over
the
[
fhapp
]
call
,
the
type
of
the
term
being
type
-
cast
appears
explicitly
in
the
goal
and
_
may
be
rewritten
as
well_
.
In
particular
,
the
final
masterstroke
is
rewriting
everywhere
in
our
goal
using
associativity
of
list
append
.
*
)
...
...
@@ -903,7 +903,7 @@ Abort.
(
*
EX
:
Show
that
the
approaches
based
on
K
and
JMeq
are
equivalent
logically
.
*
)
(
*
begin
thide
*
)
(
**
Assuming
axioms
(
like
axiom
K
and
[
JMeq_eq
])
is
a
hazardous
business
.
The
due
diligence
associated
with
it
is
necessarily
global
in
scope
,
since
two
axioms
may
be
consistent
alone
but
inconsistent
together
.
It
turns
out
that
all
of
the
major
axioms
proposed
for
reasoning
about
equality
in
Coq
are
logically
equivalent
,
so
that
we
only
need
to
pick
one
to
assert
without
proof
.
In
this
section
,
we
demonstrate
this
by
showing
how
each
of
the
previous
two
sections
'
approaches
reduces
to
the
other
logically
.
(
**
Assuming
axioms
(
like
axiom
K
and
[
JMeq_eq
])
is
a
hazardous
business
.
The
due
diligence
associated
with
it
is
necessarily
global
in
scope
,
since
two
axioms
may
be
consistent
alone
but
inconsistent
together
.
It
turns
out
that
all
of
the
major
axioms
proposed
for
reasoning
about
equality
in
Coq
are
logically
equivalent
,
so
that
we
only
need
to
pick
one
to
assert
without
proof
.
In
this
section
,
we
demonstrate
by
showing
how
each
of
the
previous
two
sections
'
approaches
reduces
to
the
other
logically
.
To
show
that
[
JMeq
]
and
its
axiom
let
us
prove
[
UIP_refl
]
,
we
start
from
the
lemma
[
UIP_refl
'
]
from
the
previous
section
.
The
rest
of
the
proof
is
trivial
.
*
)
...
...
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