SMTCoq is a Coq tool that checks proof witnesses coming from external SAT and SMT solvers.
It relies on a certified checker for such witnesses. On top of it, vernacular commands and tactics to interface with the SAT solver zChaff and the SMT solvers veriT and CVC4 are provided. It is designed in a modular way allowing to extend it easily to other solvers.
The current stable version is version 1.3.
See the INSTALL.md file for instructions.
SMTCoq is released under the CeCILL-C license; see LICENSE for more details.
Examples are given in the file examples/Example.v. They are meant to be easily re-usable for your own usage.
After installation, the SMTCoq module can be used in Coq files via the
Require Import SMTCoq.
command. For each supported solver, it
provides:
-
a vernacular command to check answers:
XXX_Checker "problem_file" "witness_file"
returnstrue
only ifwitness_file
contains a proof of the unsatisfiability of the problem stated inproblem_file
; -
a vernacular command to safely import theorems:
XXX_Theorem theo "problem_file" "witness_file"
produces a Coq termtheo
whose type is the theorem stated inproblem_file
ifwitness_file
is a proof of the unsatisfiability of it, and fails otherwise. -
safe tactics to try to solve a Coq goal using the chosen solver (or a combination of solvers).
We now give more details for each solver.
Compile and install zChaff as explained in the installation
instructions. In the following, we consider that the command zchaff
is
in your PATH
environment variable.
To check the result given by zChaff on an unsatisfiable dimacs file
file.cnf
:
-
Produce a zChaff proof witness:
zchaff file.cnf
. This command produces a proof witness file namedresolve_trace
. -
In a Coq file
file.v
, put:
Require Import SMTCoq.
Zchaff_Checker "file.cnf" "resolve_trace".
-
Compile
file.v
:coqc file.v
. If it returnstrue
then zChaff indeed proved that the problem was unsatisfiable. -
You can also produce Coq theorems from zChaff proof witnesses: the commands
Require Import SMTCoq.
Zchaff_Theorem theo "file.cnf" "resolve_trace".
will produce a Coq term theo
whose type is the theorem stated in
file.cnf
.
The zchaff
tactic can be used to solve any goal of the form:
forall l, b1 = b2
where l
is a quantifier-free list of variables and b1
and b2
are
expressions of type bool
.
Compile and install veriT as explained in the installation instructions.
In the following, we consider that the command veriT
is in your PATH
environment variable.
To check the result given by veriT on an unsatisfiable SMT-LIB2 file
file.smt2
:
- Produce a veriT proof witness:
veriT --proof-prune --proof-merge --proof-with-sharing --cnf-definitional --disable-e --disable-ackermann --input=smtlib2 --proof=file.log file.smt2
This command produces a proof witness file named file.log
.
- In a Coq file
file.v
, put:
Require Import SMTCoq.
Section File.
Verit_Checker "file.smt2" "file.log".
End File.
-
Compile
file.v
:coqc file.v
. If it returnstrue
then veriT indeed proved that the problem was unsatisfiable. -
You can also produce Coq theorems from veriT proof witnesses: the commands
Require Import SMTCoq.
Section File.
Verit_Theorem theo "file.smt2" "file.log".
End File.
will produce a Coq term theo
whose type is the theorem stated in
file.smt2
.
The theories that are currently supported by these commands are QF_UF
(theory of equality), QF_LIA
(linear integer arithmetic), QF_IDL
(integer difference logic), and their combinations.
The verit_bool
tactic can be used to solve any goal of the form:
forall l, b1 = b2
where l
is a quantifier-free list of variables and b1
and b2
are
expressions of type bool
.
In addition, the verit
tactic applies to Coq goals of sort Prop
: it
first converts the goal into a term of type bool
(thanks to the
reflect
predicate of SSReflect
), and then calls the previous tactic
verit_bool
.
The theories that are currently supported by these tactics are QF_UF
(theory of equality), QF_LIA
(linear integer arithmetic), QF_IDL
(integer difference logic), and their combinations.
Compile and install CVC4
as explained in the installation
instructions. In the following, we consider that the command cvc4
is
in your PATH
environment variable.
To check the result given by CVC4 on an unsatisfiable SMT-LIB2 file
name.smt2
:
- Produce a CVC4 proof witness:
cvc4 --dump-proof --no-simplification --fewer-preprocessing-holes --no-bv-eq --no-bv-ineq --no-bv-algebraic name.smt2 > name.lfsc
This set of commands produces a proof witness file named name.lfsc
.
- In a Coq file
name.v
, put:
Require Import SMTCoq Bool List.
Import ListNotations BVList.BITVECTOR_LIST FArray.
Local Open Scope list_scope.
Local Open Scope farray_scope.
Local Open Scope bv_scope.
Section File.
Lfsc_Checker "name.smt2" "name.lfsc".
End File.
- Compile
name.v
:coqc name.v
. If it returnstrue
then the problem is indeed unsatisfiable.
NB: Use cvc4tocoq
script in src/lfsc/tests
to automatize the above steps.
- Ex:
./cvc4tocoq name.smt2
returnstrue
only if the problemname.smt2
has been proved unsatisfiable by CVC4.
The theories that are currently supported by these commands are QF_UF
(theory of equality), QF_LIA
(linear integer arithmetic), QF_IDL
(integer difference logic), QF_BV
(theory of fixed-size bit vectors),
QF_A
(theory of arrays), and their combinations.
The cvc4_bool
tactic can be used to solve any goal of the form:
forall l, b1 = b2
where l
is a quantifier-free list of variables and b1
and b2
are
expressions of type bool
.
In addition, the cvc4
tactic applies to Coq goals of sort Prop
: it
first converts the goal into a term of type bool
(thanks to the
reflect
predicate of SSReflect
), it then calls the previous tactic
cvc4_bool
, and it finally converts any unsolved subgoals returned by
CVC4 back to Prop
, thus offering to the user the possibility to solve
these (usually simpler) subgoals.
The theories that are currently supported by these tactics are QF_UF
(theory of equality), QF_LIA
(linear integer arithmetic), QF_IDL
(integer difference logic), QF_BV
(theory of fixed-size bit vectors),
QF_A
(theory of arrays), and their combinations.
The more powerful tactic smt
combines all the previous tactics: it
first converts the goal to a term of type bool
(thanks to the
reflect
predicate of SSReflect
), it then calls a combination of the
cvc4_bool
and verit_bool
tactics, and it finally converts any
unsolved subgoals back to Prop
, thus offering to the user the
possibility to solve these (usually simpler) subgoals.