Solvers for dataflow inequations.
Require Import Coqlib.
Require Import Iteration.
Require Import Maps.
Require Import Lattice.
Local Unset Elimination Schemes.
Local Unset Case Analysis Schemes.
A forward dataflow problem is a set of inequations of the form
-
X(s) >= transf n X(n)
if program point s is a successor of program point n
-
X(n) >= a
if n is an entry point and a its minimal approximation.
The unknowns are the
X(n), indexed by program points (e.g. nodes in the
CFG graph of a RTL function). They range over a given ordered set that
represents static approximations of the program state at each point.
The
transf function is the abstract transfer function: it computes an
approximation
transf n X(n) of the program state after executing instruction
at point
n, as a function of the approximation
X(n) of the program state
before executing that instruction.
Symmetrically, a backward dataflow problem is a set of inequations of the form
-
X(n) >= transf s X(s)
if program point s is a successor of program point n
-
X(n) >= a
if n is an entry point and a its minimal approximation.
The only difference with a forward dataflow problem is that the transfer
function
transf now computes the approximation before a program point
s
from the approximation
X(s) after point
s.
This file defines three solvers for dataflow problems. The first two
solve (optimally) forward and backward problems using Kildall's worklist
algorithm. They assume that the unknowns range over a semi-lattice, that is,
an ordered type equipped with a least upper bound operation.
The last solver corresponds to propagation over extended basic blocks:
it returns approximate solutions of forward problems where the unknowns
range over any ordered type having a greatest element
top. It simply
sets
X(n) = top for all merge points
n, that is, program points having
several predecessors. This solver is useful when least upper bounds of
approximations do not exist or are too expensive to compute.
Solving forward dataflow problems using Kildall's algorithm
A forward dataflow solver has the following generic interface.
Unknowns range over the type L.t, which is equipped with
semi-lattice operations (see file Lattice).
Module Type DATAFLOW_SOLVER.
Declare Module L:
SEMILATTICE.
fixpoint successors transf ep ev is the solver.
It returns either an error or a mapping from program points to
values of type L.t representing the solution. successors
is a finite map returning the list of successors of the given program
point. transf is the transfer function, ep the entry point,
and ev the minimal abstract value for ep.
Parameter fixpoint:
forall {
A:
Type} (
code:
PTree.t A) (
successors:
A ->
list positive)
(
transf:
positive ->
L.t ->
L.t)
(
ep:
positive) (
ev:
L.t),
option (
PMap.t L.t).
The fixpoint_solution theorem shows that the returned solution,
if any, satisfies the dataflow inequations.
Axiom fixpoint_solution:
forall A (
code:
PTree.t A)
successors transf ep ev res n instr s,
fixpoint code successors transf ep ev =
Some res ->
code!
n =
Some instr ->
In s (
successors instr) ->
(
forall n,
L.eq (
transf n L.bot)
L.bot) ->
L.ge res!!
s (
transf n res!!
n).
The fixpoint_entry theorem shows that the returned solution,
if any, satisfies the additional constraint over the entry point.
Axiom fixpoint_entry:
forall A (
code:
PTree.t A)
successors transf ep ev res,
fixpoint code successors transf ep ev =
Some res ->
L.ge res!!
ep ev.
Finally, any property that is preserved by L.lub and transf
and that holds for L.bot also holds for the results of
the analysis.
Axiom fixpoint_invariant:
forall A (
code:
PTree.t A)
successors transf ep ev
(
P:
L.t ->
Prop),
P L.bot ->
(
forall x y,
P x ->
P y ->
P (
L.lub x y)) ->
(
forall pc instr x,
code!
pc =
Some instr ->
P x ->
P (
transf pc x)) ->
P ev ->
forall res pc,
fixpoint code successors transf ep ev =
Some res ->
P res!!
pc.
End DATAFLOW_SOLVER.
Kildall's algorithm manipulates worklists, which are sets of CFG nodes
equipped with a ``pick next node to examine'' operation.
The algorithm converges faster if the nodes are chosen in an order
consistent with a reverse postorder traversal of the CFG.
For now, we parameterize the dataflow solver over a module
that implements sets of CFG nodes.
Module Type NODE_SET.
Parameter t:
Type.
Parameter empty:
t.
Parameter add:
positive ->
t ->
t.
Parameter pick:
t ->
option (
positive *
t).
Parameter all_nodes:
forall {
A:
Type},
PTree.t A ->
t.
Parameter In:
positive ->
t ->
Prop.
Axiom empty_spec:
forall n, ~
In n empty.
Axiom add_spec:
forall n n'
s,
In n' (
add n s) <->
n =
n' \/
In n'
s.
Axiom pick_none:
forall s n,
pick s =
None -> ~
In n s.
Axiom pick_some:
forall s n s',
pick s =
Some(
n,
s') ->
forall n',
In n'
s <->
n =
n' \/
In n'
s'.
Axiom all_nodes_spec:
forall A (
code:
PTree.t A)
n instr,
code!
n =
Some instr ->
In n (
all_nodes code).
End NODE_SET.
Reachability in a control-flow graph.
Section REACHABLE.
Context {
A:
Type} (
code:
PTree.t A) (
successors:
A ->
list positive).
Inductive reachable:
positive ->
positive ->
Prop :=
|
reachable_refl:
forall n,
reachable n n
|
reachable_left:
forall n1 n2 n3 i,
code!
n1 =
Some i ->
In n2 (
successors i) ->
reachable n2 n3 ->
reachable n1 n3.
Scheme reachable_ind :=
Induction for reachable Sort Prop.
Lemma reachable_trans:
forall n1 n2,
reachable n1 n2 ->
forall n3,
reachable n2 n3 ->
reachable n1 n3.
Proof.
induction 1; intros.
- auto.
- econstructor; eauto.
Qed.
Lemma reachable_right:
forall n1 n2 n3 i,
reachable n1 n2 ->
code!
n2 =
Some i ->
In n3 (
successors i) ->
reachable n1 n3.
Proof.
intros.
apply reachable_trans with n2;
auto.
econstructor;
eauto.
constructor.
Qed.
End REACHABLE.
We now define a generic solver for forward dataflow inequations
that works over any semi-lattice structure.
Module Dataflow_Solver (
LAT:
SEMILATTICE) (
NS:
NODE_SET) <:
DATAFLOW_SOLVER with Module L :=
LAT.
Module L :=
LAT.
Section Kildall.
Context {
A:
Type}.
Variable code:
PTree.t A.
Variable successors:
A ->
list positive.
Variable transf:
positive ->
L.t ->
L.t.
The state of the iteration has three components:
-
aval: A mapping from program points to values of type L.t representing
the candidate solution found so far.
-
worklist: A worklist of program points that remain to be considered.
-
visited: A set of program points that were visited already
(i.e. put on the worklist at some point in the past).
Only the first two components are computationally relevant. The third
is a ghost variable used only for stating and proving invariants.
For this reason,
visited is defined at sort
Prop so that it is
erased during program extraction.
Record state :
Type :=
mkstate {
aval:
PTree.t L.t;
worklist:
NS.t;
visited:
positive ->
Prop }.
Definition abstr_value (
n:
positive) (
s:
state) :
L.t :=
match s.(
aval)!
n with
|
None =>
L.bot
|
Some v =>
v
end.
Kildall's algorithm, in pseudo-code, is as follows:
while worklist is not empty, do
extract a node n from worklist
compute out = transf n aval[n]
for each successor s of n:
compute in = lub aval[s] out
if in <> aval[s]:
aval[s] := in
worklist := worklist union {s}
visited := visited union {s}
end if
end for
end while
return aval
propagate_succ corresponds, in the pseudocode,
to the body of the for loop iterating over all successors.
Definition propagate_succ (
s:
state) (
out:
L.t) (
n:
positive) :=
match s.(
aval)!
n with
|
None =>
{|
aval :=
PTree.set n out s.(
aval);
worklist :=
NS.add n s.(
worklist);
visited :=
fun p =>
p =
n \/
s.(
visited)
p |}
|
Some oldl =>
let newl :=
L.lub oldl out in
if L.beq oldl newl
then s
else {|
aval :=
PTree.set n newl s.(
aval);
worklist :=
NS.add n s.(
worklist);
visited :=
fun p =>
p =
n \/
s.(
visited)
p |}
end.
propagate_succ_list corresponds, in the pseudocode,
to the for loop iterating over all successors.
Fixpoint propagate_succ_list (
s:
state) (
out:
L.t) (
succs:
list positive)
{
struct succs} :
state :=
match succs with
|
nil =>
s
|
n ::
rem =>
propagate_succ_list (
propagate_succ s out n)
out rem
end.
step corresponds to the body of the outer while loop in the
pseudocode.
Definition step (
s:
state) :
PMap.t L.t +
state :=
match NS.pick s.(
worklist)
with
|
None =>
inl _ (
L.bot,
s.(
aval))
|
Some(
n,
rem) =>
match code!
n with
|
None =>
inr _ {|
aval :=
s.(
aval);
worklist :=
rem;
visited :=
s.(
visited) |}
|
Some instr =>
inr _ (
propagate_succ_list
{|
aval :=
s.(
aval);
worklist :=
rem;
visited :=
s.(
visited) |}
(
transf n (
abstr_value n s))
(
successors instr))
end
end.
The whole fixpoint computation is the iteration of step from
an initial state.
Definition fixpoint_from (
start:
state) :
option (
PMap.t L.t) :=
PrimIter.iterate _ _ step start.
There are several ways to build the initial state. For forward
dataflow analyses, the initial worklist is the function entry point,
and the initial mapping sets the function entry point to the given
abstract value, and leaves unset all other program points, which
corresponds to L.bot initial abstract values.
Definition start_state (
enode:
positive) (
eval:
L.t) :=
{|
aval :=
PTree.set enode eval (
PTree.empty L.t);
worklist :=
NS.add enode NS.empty;
visited :=
fun n =>
n =
enode |}.
Definition fixpoint (
enode:
positive) (
eval:
L.t) :=
fixpoint_from (
start_state enode eval).
For backward analyses (viewed as forward analyses on the reversed CFG),
the following two variants are more useful. Both start with an
empty initial mapping, where all program points start at L.bot.
The first initializes the worklist with a given set of entry points
in the reversed CFG. (See the backward dataflow solver below for
how this list is computed.) The second start state construction
initializes the worklist with all program points of the given CFG.
Definition start_state_nodeset (
enodes:
NS.t) :=
{|
aval :=
PTree.empty L.t;
worklist :=
enodes;
visited :=
fun n =>
NS.In n enodes |}.
Definition fixpoint_nodeset (
enodes:
NS.t) :=
fixpoint_from (
start_state_nodeset enodes).
Definition start_state_allnodes :=
{|
aval :=
PTree.empty L.t;
worklist :=
NS.all_nodes code;
visited :=
fun n =>
exists instr,
code!
n =
Some instr |}.
Definition fixpoint_allnodes :=
fixpoint_from start_state_allnodes.
Characterization of the propagation functions
Inductive optge:
option L.t ->
option L.t ->
Prop :=
|
optge_some:
forall l l',
L.ge l l' ->
optge (
Some l) (
Some l')
|
optge_none:
forall ol,
optge ol None.
Remark optge_refl:
forall ol,
optge ol ol.
Proof.
Remark optge_trans:
forall ol1 ol2 ol3,
optge ol1 ol2 ->
optge ol2 ol3 ->
optge ol1 ol3.
Proof.
intros.
inv H0.
inv H.
constructor.
eapply L.ge_trans;
eauto.
constructor.
Qed.
Remark optge_abstr_value:
forall st st'
n,
optge st.(
aval)!
n st'.(
aval)!
n ->
L.ge (
abstr_value n st) (
abstr_value n st').
Proof.
Lemma propagate_succ_charact:
forall st out n,
let st' :=
propagate_succ st out n in
optge st'.(
aval)!
n (
Some out)
/\ (
forall s,
n <>
s ->
st'.(
aval)!
s =
st.(
aval)!
s)
/\ (
forall s,
optge st'.(
aval)!
s st.(
aval)!
s)
/\ (
NS.In n st'.(
worklist) \/
st'.(
aval)!
n =
st.(
aval)!
n)
/\ (
forall n',
NS.In n'
st.(
worklist) ->
NS.In n'
st'.(
worklist))
/\ (
forall n',
NS.In n'
st'.(
worklist) ->
n' =
n \/
NS.In n'
st.(
worklist))
/\ (
forall n',
st.(
visited)
n' ->
st'.(
visited)
n')
/\ (
forall n',
st'.(
visited)
n' ->
NS.In n'
st'.(
worklist) \/
st.(
visited)
n')
/\ (
forall n',
st.(
aval)!
n' =
None ->
st'.(
aval)!
n' <>
None ->
st'.(
visited)
n').
Proof.
Lemma propagate_succ_list_charact:
forall out l st,
let st' :=
propagate_succ_list st out l in
(
forall n,
In n l ->
optge st'.(
aval)!
n (
Some out))
/\ (
forall n, ~
In n l ->
st'.(
aval)!
n =
st.(
aval)!
n)
/\ (
forall n,
optge st'.(
aval)!
n st.(
aval)!
n)
/\ (
forall n,
NS.In n st'.(
worklist) \/
st'.(
aval)!
n =
st.(
aval)!
n)
/\ (
forall n',
NS.In n'
st.(
worklist) ->
NS.In n'
st'.(
worklist))
/\ (
forall n',
NS.In n'
st'.(
worklist) ->
In n'
l \/
NS.In n'
st.(
worklist))
/\ (
forall n',
st.(
visited)
n' ->
st'.(
visited)
n')
/\ (
forall n',
st'.(
visited)
n' ->
NS.In n'
st'.(
worklist) \/
st.(
visited)
n')
/\ (
forall n',
st.(
aval)!
n' =
None ->
st'.(
aval)!
n' <>
None ->
st'.(
visited)
n').
Proof.
induction l;
simpl;
intros.
-
repeat split;
intros.
+
contradiction.
+
apply optge_refl.
+
auto.
+
auto.
+
auto.
+
auto.
+
auto.
+
congruence.
-
generalize (
propagate_succ_charact st out a).
set (
st1 :=
propagate_succ st out a).
intros (
A1 &
A2 &
A3 &
A4 &
A5 &
A6 &
A7 &
A8 &
A9).
generalize (
IHl st1).
set (
st2 :=
propagate_succ_list st1 out l).
intros (
B1 &
B2 &
B3 &
B4 &
B5 &
B6 &
B7 &
B8 &
B9).
clear IHl.
repeat split;
intros.
+
destruct H.
*
subst n.
eapply optge_trans;
eauto.
*
auto.
+
rewrite B2 by tauto.
apply A2;
tauto.
+
eapply optge_trans;
eauto.
+
destruct (
B4 n).
auto.
destruct (
peq n a).
*
subst n.
destruct A4.
left;
auto.
right;
congruence.
*
right.
rewrite H.
auto.
+
eauto.
+
exploit B6;
eauto.
intros [
P|
P].
auto.
exploit A6;
eauto.
intuition.
+
eauto.
+
specialize (
B8 n');
specialize (
A8 n').
intuition.
+
destruct st1.(
aval)!
n'
eqn:
ST1.
apply B7.
apply A9;
auto.
congruence.
apply B9;
auto.
Qed.
Characterization of fixpoint_from.
Inductive steps:
state ->
state ->
Prop :=
|
steps_base:
forall s,
steps s s
|
steps_right:
forall s1 s2 s3,
steps s1 s2 ->
step s2 =
inr s3 ->
steps s1 s3.
Scheme steps_ind :=
Induction for steps Sort Prop.
Lemma fixpoint_from_charact:
forall start res,
fixpoint_from start =
Some res ->
exists st,
steps start st /\
NS.pick st.(
worklist) =
None /\
res = (
L.bot,
st.(
aval)).
Proof.
Monotonicity properties
We first show that the
aval and
visited parts of the state
evolve monotonically:
-
at each step, the values of the aval[n] either remain the same or
increase with respect to the optge ordering;
-
every node visited in the past remains visited in the future.
Lemma step_incr:
forall n s1 s2,
step s1 =
inr s2 ->
optge s2.(
aval)!
n s1.(
aval)!
n /\ (
s1.(
visited)
n ->
s2.(
visited)
n).
Proof.
Lemma steps_incr:
forall n s1 s2,
steps s1 s2 ->
optge s2.(
aval)!
n s1.(
aval)!
n /\ (
s1.(
visited)
n ->
s2.(
visited)
n).
Proof.
induction 1.
-
split.
apply optge_refl.
auto.
-
destruct IHsteps.
exploit (
step_incr n);
eauto.
intros [
P Q].
split.
eapply optge_trans;
eauto.
eauto.
Qed.
Correctness invariant
The following invariant is preserved at each iteration of Kildall's
algorithm: for all visited program point n, either
n is in the worklist, or the inequations associated with n
(aval[s] >= transf n aval[n] for all successors s of n)
hold. In other terms, the worklist contains all nodes that were
visited but do not yet satisfy their inequations.
The second part of the invariant shows that nodes that already have
an abstract value associated with them have been visited.
Record good_state (
st:
state) :
Prop := {
gs_stable:
forall n,
st.(
visited)
n ->
NS.In n st.(
worklist) \/
(
forall i s,
code!
n =
Some i ->
In s (
successors i) ->
optge st.(
aval)!
s (
Some (
transf n (
abstr_value n st))));
gs_defined:
forall n v,
st.(
aval)!
n =
Some v ->
st.(
visited)
n
}.
We show that the step function preserves this invariant.
Lemma step_state_good:
forall st pc rem instr,
NS.pick st.(
worklist) =
Some (
pc,
rem) ->
code!
pc =
Some instr ->
good_state st ->
good_state (
propagate_succ_list (
mkstate st.(
aval)
rem st.(
visited))
(
transf pc (
abstr_value pc st))
(
successors instr)).
Proof.
intros until instr;
intros PICK CODEAT [
GOOD1 GOOD2].
generalize (
NS.pick_some _ _ _ PICK);
intro PICK2.
set (
out :=
transf pc (
abstr_value pc st)).
generalize (
propagate_succ_list_charact out (
successors instr) {|
aval :=
aval st;
worklist :=
rem;
visited :=
visited st |}).
set (
st' :=
propagate_succ_list {|
aval :=
aval st;
worklist :=
rem;
visited :=
visited st |}
out
(
successors instr)).
simpl;
intros (
A1 &
A2 &
A3 &
A4 &
A5 &
A6 &
A7 &
A8 &
A9).
constructor;
intros.
-
destruct (
A8 n H);
auto.
destruct (
A4 n);
auto.
replace (
abstr_value n st')
with (
abstr_value n st)
by (
unfold abstr_value;
rewrite H1;
auto).
exploit GOOD1;
eauto.
intros [
P|
P].
+
rewrite PICK2 in P;
destruct P.
*
subst n.
fold out.
right;
intros.
assert (
i =
instr)
by congruence.
subst i.
apply A1;
auto.
*
left.
apply A5;
auto.
+
right;
intros.
apply optge_trans with st.(
aval)!
s;
eauto.
-
destruct st.(
aval)!
n as [
v'|]
eqn:
ST.
+
apply A7.
eapply GOOD2;
eauto.
+
apply A9;
auto.
congruence.
Qed.
Lemma step_state_good_2:
forall st pc rem,
good_state st ->
NS.pick (
worklist st) =
Some (
pc,
rem) ->
code!
pc =
None ->
good_state (
mkstate st.(
aval)
rem st.(
visited)).
Proof.
intros until rem;
intros [
GOOD1 GOOD2]
PICK CODE.
generalize (
NS.pick_some _ _ _ PICK);
intro PICK2.
constructor;
simpl;
intros.
-
exploit GOOD1;
eauto.
intros [
P |
P].
+
rewrite PICK2 in P.
destruct P;
auto.
subst n.
right;
intros.
congruence.
+
right;
exact P.
-
eapply GOOD2;
eauto.
Qed.
Lemma steps_state_good:
forall st1 st2,
steps st1 st2 ->
good_state st1 ->
good_state st2.
Proof.
We show that initial states satisfy the invariant.
Lemma start_state_good:
forall enode eval,
good_state (
start_state enode eval).
Proof.
Lemma start_state_nodeset_good:
forall enodes,
good_state (
start_state_nodeset enodes).
Proof.
Lemma start_state_allnodes_good:
good_state start_state_allnodes.
Proof.
Reachability in final states.
Lemma reachable_visited:
forall st,
good_state st ->
NS.pick st.(
worklist) =
None ->
forall p q,
reachable code successors p q ->
st.(
visited)
p ->
st.(
visited)
q.
Proof.
intros st [
GOOD1 GOOD2]
PICK.
induction 1;
intros.
-
auto.
-
eapply IHreachable;
eauto.
exploit GOOD1;
eauto.
intros [
P |
P].
eelim NS.pick_none;
eauto.
exploit P;
eauto.
intros OGE;
inv OGE.
eapply GOOD2;
eauto.
Qed.
Correctness of the solution returned by fixpoint.
As a consequence of the good_state invariant, the result of
fixpoint, if defined, is a solution of the dataflow inequations.
This assumes that the transfer function maps L.bot to L.bot.
Theorem fixpoint_solution:
forall ep ev res n instr s,
fixpoint ep ev =
Some res ->
code!
n =
Some instr ->
In s (
successors instr) ->
(
forall n,
L.eq (
transf n L.bot)
L.bot) ->
L.ge res!!
s (
transf n res!!
n).
Proof.
Moreover, the result of fixpoint, if defined, satisfies the additional
constraint given on the entry point.
Theorem fixpoint_entry:
forall ep ev res,
fixpoint ep ev =
Some res ->
L.ge res!!
ep ev.
Proof.
For fixpoint_allnodes, we show that the result is a solution
without assuming transf n L.bot = L.bot.
Theorem fixpoint_allnodes_solution:
forall res n instr s,
fixpoint_allnodes =
Some res ->
code!
n =
Some instr ->
In s (
successors instr) ->
L.ge res!!
s (
transf n res!!
n).
Proof.
For fixpoint_nodeset, we show that the result is a solution
at all program points that are reachable from the given entry points.
Theorem fixpoint_nodeset_solution:
forall enodes res e n instr s,
fixpoint_nodeset enodes =
Some res ->
NS.In e enodes ->
reachable code successors e n ->
code!
n =
Some instr ->
In s (
successors instr) ->
L.ge res!!
s (
transf n res!!
n).
Proof.
Preservation of a property over solutions
Theorem fixpoint_invariant:
forall ep ev
(
P:
L.t ->
Prop)
(
P_bot:
P L.bot)
(
P_lub:
forall x y,
P x ->
P y ->
P (
L.lub x y))
(
P_transf:
forall pc instr x,
code!
pc =
Some instr ->
P x ->
P (
transf pc x))
(
P_entrypoint:
P ev)
res pc,
fixpoint ep ev =
Some res ->
P res!!
pc.
Proof.
End Kildall.
End Dataflow_Solver.
Solving backward dataflow problems using Kildall's algorithm
A backward dataflow problem on a given flow graph is a forward
dataflow program on the reversed flow graph, where predecessors replace
successors. We exploit this observation to cheaply derive a backward
solver from the forward solver.
Construction of the reversed flow graph (the predecessor relation)
Definition successors_list (
successors:
PTree.t (
list positive)) (
pc:
positive) :
list positive :=
match successors!
pc with None =>
nil |
Some l =>
l end.
Notation "
a !!!
b" := (
successors_list a b) (
at level 1).
Section Predecessor.
Context {
A:
Type}.
Variable code:
PTree.t A.
Variable successors:
A ->
list positive.
Fixpoint add_successors (
pred:
PTree.t (
list positive))
(
from:
positive) (
tolist:
list positive)
{
struct tolist} :
PTree.t (
list positive) :=
match tolist with
|
nil =>
pred
|
to ::
rem =>
add_successors (
PTree.set to (
from ::
pred!!!
to)
pred)
from rem
end.
Lemma add_successors_correct:
forall tolist from pred n s,
In n pred!!!
s \/ (
n =
from /\
In s tolist) ->
In n (
add_successors pred from tolist)!!!
s.
Proof.
induction tolist;
simpl;
intros.
tauto.
apply IHtolist.
unfold successors_list at 1.
rewrite PTree.gsspec.
destruct (
peq s a).
subst a.
destruct H.
auto with coqlib.
destruct H.
subst n.
auto with coqlib.
fold (
successors_list pred s).
intuition congruence.
Qed.
Definition make_predecessors :
PTree.t (
list positive) :=
PTree.fold (
fun pred pc instr =>
add_successors pred pc (
successors instr))
code (
PTree.empty (
list positive)).
Lemma make_predecessors_correct_1:
forall n instr s,
code!
n =
Some instr ->
In s (
successors instr) ->
In n make_predecessors!!!
s.
Proof.
Lemma make_predecessors_correct_2:
forall n instr s,
code!
n =
Some instr ->
In s (
successors instr) ->
exists l,
make_predecessors!
s =
Some l /\
In n l.
Proof.
Lemma reachable_predecessors:
forall p q,
reachable code successors p q ->
reachable make_predecessors (
fun l =>
l)
q p.
Proof.
End Predecessor.
Solving backward dataflow problems
The interface to a backward dataflow solver is as follows.
Module Type BACKWARD_DATAFLOW_SOLVER.
Declare Module L:
SEMILATTICE.
fixpoint successors transf is the solver.
It returns either an error or a mapping from program points to
values of type L.t representing the solution. successors
is a finite map returning the list of successors of the given program
point. transf is the transfer function.
Parameter fixpoint:
forall {
A:
Type} (
code:
PTree.t A) (
successors:
A ->
list positive)
(
transf:
positive ->
L.t ->
L.t),
option (
PMap.t L.t).
The fixpoint_solution theorem shows that the returned solution,
if any, satisfies the backward dataflow inequations.
Axiom fixpoint_solution:
forall A (
code:
PTree.t A)
successors transf res n instr s,
fixpoint code successors transf =
Some res ->
code!
n =
Some instr ->
In s (
successors instr) ->
(
forall n a,
code!
n =
None ->
L.eq (
transf n a)
L.bot) ->
L.ge res!!
n (
transf s res!!
s).
fixpoint_allnodes is a variant of fixpoint, less algorithmically
efficient, but correct without any hypothesis on the transfer function.
Parameter fixpoint_allnodes:
forall {
A:
Type} (
code:
PTree.t A) (
successors:
A ->
list positive)
(
transf:
positive ->
L.t ->
L.t),
option (
PMap.t L.t).
Axiom fixpoint_allnodes_solution:
forall A (
code:
PTree.t A)
successors transf res n instr s,
fixpoint_allnodes code successors transf =
Some res ->
code!
n =
Some instr ->
In s (
successors instr) ->
L.ge res!!
n (
transf s res!!
s).
End BACKWARD_DATAFLOW_SOLVER.
We construct a generic backward dataflow solver, working over any
semi-lattice structure, by applying the forward dataflow solver
with the predecessor relation instead of the successor relation.
Module Backward_Dataflow_Solver (
LAT:
SEMILATTICE) (
NS:
NODE_SET):
BACKWARD_DATAFLOW_SOLVER with Module L :=
LAT.
Module L :=
LAT.
Module DS :=
Dataflow_Solver L NS.
Section Kildall.
Context {
A:
Type}.
Variable code:
PTree.t A.
Variable successors:
A ->
list positive.
Variable transf:
positive ->
L.t ->
L.t.
Finding entry points for the reverse control-flow graph.
Section Exit_points.
Assuming that the nodes of the CFG code are numbered in reverse
postorder (cf. pass Renumber), an edge from n to s is a
normal edge if s < n and a back-edge otherwise.
sequential_node returns true if the given node has at least one
normal outgoing edge. It returns false if the given node is an exit
node (no outgoing edges) or the final node of a loop body
(all outgoing edges are back-edges). As we prove later, the set
of all non-sequential node is an appropriate set of entry points
for exploring the reverse CFG.
Definition sequential_node (
pc:
positive) (
instr:
A):
bool :=
existsb (
fun s =>
match code!
s with None =>
false |
Some _ =>
plt s pc end)
(
successors instr).
Definition exit_points :
NS.t :=
PTree.fold
(
fun ep pc instr =>
if sequential_node pc instr
then ep
else NS.add pc ep)
code NS.empty.
Lemma exit_points_charact:
forall n,
NS.In n exit_points <->
exists i,
code!
n =
Some i /\
sequential_node n i =
false.
Proof.
intros n.
unfold exit_points.
eapply PTree_Properties.fold_rec.
-
intros.
rewrite <-
H.
auto.
-
simpl.
split;
intros.
eelim NS.empty_spec;
eauto.
destruct H as [
i [
P Q]].
rewrite PTree.gempty in P.
congruence.
-
intros.
destruct (
sequential_node k v)
eqn:
SN.
+
rewrite H1.
rewrite PTree.gsspec.
destruct (
peq n k).
subst.
split;
intros [
i [
P Q]].
congruence.
inv P.
congruence.
tauto.
+
rewrite NS.add_spec.
rewrite H1.
rewrite PTree.gsspec.
destruct (
peq n k).
subst.
split.
intros.
exists v;
auto.
auto.
split.
intros [
P | [
i [
P Q]]].
congruence.
exists i;
auto.
intros [
i [
P Q]].
right;
exists i;
auto.
Qed.
Lemma reachable_exit_points:
forall pc i,
code!
pc =
Some i ->
exists x,
NS.In x exit_points /\
reachable code successors pc x.
Proof.
The crucial property of exit points is that any nonempty node in the
CFG is reverse-reachable from an exit point.
Lemma reachable_exit_points_predecessor:
forall pc i,
code!
pc =
Some i ->
exists x,
NS.In x exit_points /\
reachable (
make_predecessors code successors) (
fun l =>
l)
x pc.
Proof.
End Exit_points.
The efficient backward solver.
Definition fixpoint :=
DS.fixpoint_nodeset
(
make_predecessors code successors) (
fun l =>
l)
transf exit_points.
Theorem fixpoint_solution:
forall res n instr s,
fixpoint =
Some res ->
code!
n =
Some instr ->
In s (
successors instr) ->
(
forall n a,
code!
n =
None ->
L.eq (
transf n a)
L.bot) ->
L.ge res!!
n (
transf s res!!
s).
Proof.
The alternate solver that starts with all nodes of the CFG instead
of just the exit points.
Definition fixpoint_allnodes :=
DS.fixpoint_allnodes
(
make_predecessors code successors) (
fun l =>
l)
transf.
Theorem fixpoint_allnodes_solution:
forall res n instr s,
fixpoint_allnodes =
Some res ->
code!
n =
Some instr ->
In s (
successors instr) ->
L.ge res!!
n (
transf s res!!
s).
Proof.
End Kildall.
End Backward_Dataflow_Solver.
Analysis on extended basic blocks
We now define an approximate solver for forward dataflow problems
that proceeds by forward propagation over extended basic blocks.
In other terms, program points with multiple predecessors are mapped
to L.top (the greatest, or coarsest, approximation) and the other
program points are mapped to transf p X[p] where p is their unique
predecessor.
This analysis applies to any type of approximations equipped with
an ordering and a greatest element.
Module Type ORDERED_TYPE_WITH_TOP.
Parameter t:
Type.
Parameter ge:
t ->
t ->
Prop.
Parameter top:
t.
Axiom top_ge:
forall x,
ge top x.
Axiom refl_ge:
forall x,
ge x x.
End ORDERED_TYPE_WITH_TOP.
The interface of the solver is similar to that of Kildall's forward
solver, with a slightly different statement of the invariant
preservation property fixpoint_invariant.
Module Type BBLOCK_SOLVER.
Declare Module L:
ORDERED_TYPE_WITH_TOP.
Parameter fixpoint:
forall {
A:
Type} (
code:
PTree.t A) (
successors:
A ->
list positive)
(
transf:
positive ->
L.t ->
L.t)
(
entrypoint:
positive),
option (
PMap.t L.t).
Axiom fixpoint_solution:
forall A (
code:
PTree.t A)
successors transf entrypoint res n instr s,
fixpoint code successors transf entrypoint =
Some res ->
code!
n =
Some instr ->
In s (
successors instr) ->
L.ge res!!
s (
transf n res!!
n).
Axiom fixpoint_entry:
forall A (
code:
PTree.t A)
successors transf entrypoint res,
fixpoint code successors transf entrypoint =
Some res ->
res!!
entrypoint =
L.top.
Axiom fixpoint_invariant:
forall A (
code:
PTree.t A)
successors transf entrypoint
(
P:
L.t ->
Prop),
P L.top ->
(
forall pc instr x,
code!
pc =
Some instr ->
P x ->
P (
transf pc x)) ->
forall res pc,
fixpoint code successors transf entrypoint =
Some res ->
P res!!
pc.
End BBLOCK_SOLVER.
The implementation of the ``extended basic block'' solver is a
functor parameterized by any ordered type with a top element.
Module BBlock_solver(
LAT:
ORDERED_TYPE_WITH_TOP):
BBLOCK_SOLVER with Module L :=
LAT.
Module L :=
LAT.
Section Solver.
Context {
A:
Type}.
Variable code:
PTree.t A.
Variable successors:
A ->
list positive.
Variable transf:
positive ->
L.t ->
L.t.
Variable entrypoint:
positive.
Variable P:
L.t ->
Prop.
Hypothesis Ptop:
P L.top.
Hypothesis Ptransf:
forall pc instr x,
code!
pc =
Some instr ->
P x ->
P (
transf pc x).
Definition bbmap :=
positive ->
bool.
Definition result :=
PMap.t L.t.
As in Kildall's solver, the state of the iteration has two components:
-
A mapping from program points to values of type L.t representing
the candidate solution found so far.
-
A worklist of program points that remain to be considered.
Record state :
Type :=
mkstate
{
aval:
result;
worklist:
list positive }.
The ``extended basic block'' algorithm, in pseudo-code, is as follows:
worklist := the set of all points n having multiple predecessors
aval := the mapping n -> L.top
while worklist is not empty, do
extract a node n from worklist
compute out = transf n aval[n]
for each successor s of n:
if s has only one predecessor (namely, n):
aval[s] := out
worklist := worklist union {s}
end if
end for
end while
return aval
*
Fixpoint propagate_successors
(
bb:
bbmap) (
succs:
list positive) (
l:
L.t) (
st:
state)
{
struct succs} :
state :=
match succs with
|
nil =>
st
|
s1 ::
sl =>
if bb s1 then
propagate_successors bb sl l st
else
propagate_successors bb sl l
(
mkstate (
PMap.set s1 l st.(
aval))
(
s1 ::
st.(
worklist)))
end.
Definition step (
bb:
bbmap) (
st:
state) :
result +
state :=
match st.(
worklist)
with
|
nil =>
inl _ st.(
aval)
|
pc ::
rem =>
match code!
pc with
|
None =>
inr _ (
mkstate st.(
aval)
rem)
|
Some instr =>
inr _ (
propagate_successors
bb (
successors instr)
(
transf pc st.(
aval)!!
pc)
(
mkstate st.(
aval)
rem))
end
end.
Recognition of program points that have more than one predecessor.
Definition is_basic_block_head
(
preds:
PTree.t (
list positive)) (
pc:
positive) :
bool :=
if peq pc entrypoint then true else
match preds!!!
pc with
|
nil =>
false
|
s ::
nil =>
peq s pc
|
_ ::
_ ::
_ =>
true
end.
Definition basic_block_map :
bbmap :=
is_basic_block_head (
make_predecessors code successors).
Definition basic_block_list (
bb:
bbmap) :
list positive :=
PTree.fold (
fun l pc instr =>
if bb pc then pc ::
l else l)
code nil.
The computation of the approximate solution.
Definition fixpoint :
option result :=
let bb :=
basic_block_map in
PrimIter.iterate _ _ (
step bb) (
mkstate (
PMap.init L.top) (
basic_block_list bb)).
Properties of predecessors and multiple-predecessors nodes
Definition predecessors :=
make_predecessors code successors.
Lemma predecessors_correct:
forall n instr s,
code!
n =
Some instr ->
In s (
successors instr) ->
In n predecessors!!!
s.
Proof.
Lemma multiple_predecessors:
forall s n1 instr1 n2 instr2,
code!
n1 =
Some instr1 ->
In s (
successors instr1) ->
code!
n2 =
Some instr2 ->
In s (
successors instr2) ->
n1 <>
n2 ->
basic_block_map s =
true.
Proof.
Lemma no_self_loop:
forall n instr,
code!
n =
Some instr ->
In n (
successors instr) ->
basic_block_map n =
true.
Proof.
Correctness invariant
The invariant over the state is as follows:
-
Points with several predecessors are mapped to L.top
-
Points not in the worklist satisfy their inequations
(as in Kildall's algorithm).
Definition state_invariant (
st:
state) :
Prop :=
(
forall n,
basic_block_map n =
true ->
st.(
aval)!!
n =
L.top)
/\
(
forall n,
In n st.(
worklist) \/
(
forall instr s,
code!
n =
Some instr ->
In s (
successors instr) ->
L.ge st.(
aval)!!
s (
transf n st.(
aval)!!
n))).
Lemma propagate_successors_charact1:
forall bb succs l st,
incl st.(
worklist)
(
propagate_successors bb succs l st).(
worklist).
Proof.
Lemma propagate_successors_charact2:
forall bb succs l st n,
let st' :=
propagate_successors bb succs l st in
(
In n succs ->
bb n =
false ->
In n st'.(
worklist) /\
st'.(
aval)!!
n =
l)
/\ (~
In n succs \/
bb n =
true ->
st'.(
aval)!!
n =
st.(
aval)!!
n).
Proof.
induction succs;
simpl;
intros.
Base case *)
split.
tauto.
auto.
Inductive case *)
caseEq (
bb a);
intro.
elim (
IHsuccs l st n);
intros U V.
split;
intros.
apply U;
auto.
elim H0;
intro.
subst a.
congruence.
auto.
apply V.
tauto.
set (
st1 :=
mkstate (
PMap.set a l (
aval st)) (
a ::
worklist st)).
elim (
IHsuccs l st1 n);
intros U V.
split;
intros.
elim H0;
intros.
subst n.
split.
apply propagate_successors_charact1.
simpl.
tauto.
case (
In_dec peq a succs);
intro.
elim (
U i H1);
auto.
rewrite V.
unfold st1;
simpl.
apply PMap.gss.
tauto.
apply U;
auto.
rewrite V.
unfold st1;
simpl.
apply PMap.gso.
red;
intro;
subst n.
elim H0;
intro.
tauto.
congruence.
tauto.
Qed.
Lemma propagate_successors_invariant:
forall pc instr res rem,
code!
pc =
Some instr ->
state_invariant (
mkstate res (
pc ::
rem)) ->
state_invariant
(
propagate_successors basic_block_map (
successors instr)
(
transf pc res!!
pc)
(
mkstate res rem)).
Proof.
intros until rem.
intros CODE [
INV1 INV2].
simpl in INV1.
simpl in INV2.
set (
l :=
transf pc res!!
pc).
generalize (
propagate_successors_charact1 basic_block_map
(
successors instr)
l (
mkstate res rem)).
generalize (
propagate_successors_charact2 basic_block_map
(
successors instr)
l (
mkstate res rem)).
set (
st1 :=
propagate_successors basic_block_map
(
successors instr)
l (
mkstate res rem)).
intros U V.
simpl in U.
First part: BB entries remain at top *)
split;
intros.
elim (
U n);
intros C D.
rewrite D.
simpl.
apply INV1.
auto.
tauto.
Second part: monotonicity *) Case 1: n = pc *)
destruct (
peq pc n).
subst n.
right;
intros.
assert (
instr0 =
instr)
by congruence.
subst instr0.
elim (
U s);
intros C D.
replace (
st1.(
aval)!!
pc)
with res!!
pc.
fold l.
destruct (
basic_block_map s)
eqn:
BB.
rewrite D.
simpl.
rewrite INV1.
apply L.top_ge.
auto.
tauto.
elim (
C H0 (
eq_refl _)).
intros X Y.
rewrite Y.
apply L.refl_ge.
elim (
U pc);
intros E F.
rewrite F.
reflexivity.
destruct (
In_dec peq pc (
successors instr)).
right.
eapply no_self_loop;
eauto.
left;
auto.
Case 2: n <> pc *)
elim (
INV2 n);
intro.
Case 2.1: n was already in worklist, still is *)
left.
apply V.
simpl.
tauto.
Case 2.2: n was not in worklist *)
assert (
INV3:
forall s instr',
code!
n =
Some instr' ->
In s (
successors instr') ->
st1.(
aval)!!
s =
res!!
s).
Amazingly, successors of n do not change. The only way
they could change is if they were successors of pc as well,
but that gives them two different predecessors, so
they are basic block heads, and thus do not change! *)
intros.
elim (
U s);
intros C D.
rewrite D.
reflexivity.
destruct (
In_dec peq s (
successors instr)).
right.
eapply multiple_predecessors with (
n1 :=
pc) (
n2 :=
n);
eauto.
left;
auto.
destruct (
In_dec peq n (
successors instr)).
Case 2.2.1: n is a successor of pc. Either it is in the
worklist or it did not change *)
destruct (
basic_block_map n)
eqn:
BB.
right;
intros.
elim (
U n);
intros C D.
rewrite D.
erewrite INV3;
eauto.
tauto.
left.
elim (
U n);
intros C D.
elim (
C i BB);
intros.
auto.
Case 2.2.2: n is not a successor of pc. It did not change. *)
right;
intros.
elim (
U n);
intros C D.
rewrite D.
erewrite INV3;
eauto.
tauto.
Qed.
Lemma propagate_successors_invariant_2:
forall pc res rem,
code!
pc =
None ->
state_invariant (
mkstate res (
pc ::
rem)) ->
state_invariant (
mkstate res rem).
Proof.
intros until rem. intros CODE [INV1 INV2]. simpl in INV1. simpl in INV2.
split; simpl; intros.
apply INV1; auto.
destruct (INV2 n) as [[U | U] | U].
subst n. right; intros; congruence.
auto.
auto.
Qed.
Lemma initial_state_invariant:
state_invariant (
mkstate (
PMap.init L.top) (
basic_block_list basic_block_map)).
Proof.
Lemma analyze_invariant:
forall res,
fixpoint =
Some res ->
state_invariant (
mkstate res nil).
Proof.
Correctness of the returned solution
Theorem fixpoint_solution:
forall res n instr s,
fixpoint =
Some res ->
code!
n =
Some instr ->
In s (
successors instr) ->
L.ge res!!
s (
transf n res!!
n).
Proof.
Theorem fixpoint_entry:
forall res,
fixpoint =
Some res ->
res!!
entrypoint =
L.top.
Proof.
Preservation of a property over solutions
Definition Pstate (
st:
state) :
Prop :=
forall pc,
P st.(
aval)!!
pc.
Lemma propagate_successors_P:
forall bb l,
P l ->
forall succs st,
Pstate st ->
Pstate (
propagate_successors bb succs l st).
Proof.
induction succs;
simpl;
intros.
auto.
case (
bb a).
auto.
apply IHsuccs.
red;
simpl;
intros.
rewrite PMap.gsspec.
case (
peq pc a);
intro.
auto.
apply H0.
Qed.
Theorem fixpoint_invariant:
forall res pc,
fixpoint =
Some res ->
P res!!
pc.
Proof.
End Solver.
End BBlock_solver.
Node sets
We now define implementations of the NODE_SET interface
appropriate for forward and backward dataflow analysis.
As mentioned earlier, we aim for a traversal of the CFG nodes
in reverse postorder (for forward analysis) or postorder
(for backward analysis). We take advantage of the following
fact, valid for all CFG generated by translation from Cminor:
the enumeration n-1, n-2, ..., 3, 2, 1 where n is the
top CFG node is a reverse postorder traversal.
Therefore, for forward analysis, we will use an implementation
of NODE_SET where the pick operation selects the
greatest node in the working list. For backward analysis,
we will similarly pick the smallest node in the working list.
Require Import Heaps.
Module NodeSetForward <:
NODE_SET.
Definition t :=
PHeap.t.
Definition empty :=
PHeap.empty.
Definition add (
n:
positive) (
s:
t) :
t :=
PHeap.insert n s.
Definition pick (
s:
t) :=
match PHeap.findMax s with
|
Some n =>
Some(
n,
PHeap.deleteMax s)
|
None =>
None
end.
Definition all_nodes {
A:
Type} (
code:
PTree.t A) :=
PTree.fold (
fun s pc instr =>
PHeap.insert pc s)
code PHeap.empty.
Definition In :=
PHeap.In.
Lemma empty_spec:
forall n, ~
In n empty.
Proof.
Lemma add_spec:
forall n n'
s,
In n' (
add n s) <->
n =
n' \/
In n'
s.
Proof.
Lemma pick_none:
forall s n,
pick s =
None -> ~
In n s.
Proof.
Lemma pick_some:
forall s n s',
pick s =
Some(
n,
s') ->
forall n',
In n'
s <->
n =
n' \/
In n'
s'.
Proof.
Lemma all_nodes_spec:
forall A (
code:
PTree.t A)
n instr,
code!
n =
Some instr ->
In n (
all_nodes code).
Proof.
End NodeSetForward.
Module NodeSetBackward <:
NODE_SET.
Definition t :=
PHeap.t.
Definition empty :=
PHeap.empty.
Definition add (
n:
positive) (
s:
t) :
t :=
PHeap.insert n s.
Definition pick (
s:
t) :=
match PHeap.findMin s with
|
Some n =>
Some(
n,
PHeap.deleteMin s)
|
None =>
None
end.
Definition all_nodes {
A:
Type} (
code:
PTree.t A) :=
PTree.fold (
fun s pc instr =>
PHeap.insert pc s)
code PHeap.empty.
Definition In :=
PHeap.In.
Lemma empty_spec:
forall n, ~
In n empty.
Proof NodeSetForward.empty_spec.
Lemma add_spec:
forall n n'
s,
In n' (
add n s) <->
n =
n' \/
In n'
s.
Proof NodeSetForward.add_spec.
Lemma pick_none:
forall s n,
pick s =
None -> ~
In n s.
Proof.
Lemma pick_some:
forall s n s',
pick s =
Some(
n,
s') ->
forall n',
In n'
s <->
n =
n' \/
In n'
s'.
Proof.
Lemma all_nodes_spec:
forall A (
code:
PTree.t A)
n instr,
code!
n =
Some instr ->
In n (
all_nodes code).
Proof NodeSetForward.all_nodes_spec.
End NodeSetBackward.