package bitwuzla-cxx

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SMT solver for AUFBVFP (C++ API)

Install

Dune Dependency

Authors

Maintainers

Sources

bitwuzla-cxx-0.6.1.tbz
sha256=420672d1ae103d5920881fa5844c38d2913d4deb8e39e328c2d51bd05f8137a7
sha512=99fb414c9bba4f120d10696f83a915c6bd14661f7e424792e0a30f0ff2bd4a59832207d83ad4004bed36da827023c54e588de566d3ec97ed305b7f2e121f611e

Description

OCaml binding for the SMT solver Bitwuzla C++ API.

Bitwuzla is a Satisfiability Modulo Theories (SMT) solver for the theories of fixed-size bit-vectors, arrays and uninterpreted functions and their combinations. Its name is derived from an Austrian dialect expression that can be translated as “someone who tinkers with bits”.

Tags

SMT solver AUFBVFP

Published: 15 Nov 2024

README

README.md

ocaml-bitwuzla

Bitwuzla is a Satisfiability Modulo Theories (SMT) solvers for the theories of fixed-size bit-vectors, floating-point arithmetic, arrays, uninterpreted functions and their combinations.

This library provides an API for using Bitwuzla in OCaml code. Online documentation is available at https://bitwuzla.github.io/docs/ocaml.

Quickstart

First, create a Options instance:

let options = Options.default () in

This instance can be configured via Options.set. For example, to enable model generation (SMT-LIB: (set-option :produce-models true)):

Options.set options Produce_models true;

Then, create a Bitwuzla instance (configuration options are now frozen and cannot be changed for this instance):

let bitwuzla = Solver.create options in

Next, you will want to create some expressions and assert formulas. For example, consider the following SMT-LIB input:

(set-logic QF_ABV)
(set-option :produce-models true)
(declare-const x (_ BitVec 8))
(declare-const y (_ BitVec 8))
(declare-fun f ((_ BitVec 8) (_ BitVec 4)) (_ BitVec 8))
(declare-const a (Array (_ BitVec 8) (_ BitVec 8)))
(assert
    (distinct
        ((_ extract 3 0) (bvsdiv x (_ bv2 8)))
        ((_ extract 3 0) (bvashr y (_ bv1 8)))))
(assert (= (f x ((_ extract 6 3) x)) y))
(assert (= (select a x) y))
(check-sat)
(get-model)
(get-value (x y f a (bvmul x x)))
(exit)

This input is created and asserted as follows:

  (* Create bit-vector sorts of size 4 and 8. *)
  let sortbv4 = mk_bv_sort 4 and sortbv8 = mk_bv_sort 8 in
  (* Create function sort. *)
  let sortfun = mk_fun_sort [| sortbv8; sortbv4 |] sortbv8 in
  (* Create array sort. *)
  let sortarr = mk_array_sort sortbv8 sortbv8 in

  (* Create two bit-vector constants of that sort. *)
  let x = mk_const sortbv8 ~symbol:"x" and y = mk_const sortbv8 ~symbol:"y" in
  (* Create fun const. *)
  let f = mk_const sortfun ~symbol:"f" in
  (* Create array const. *)
  let a = mk_const sortarr ~symbol:"a" in

  (* Create bit-vector values one and two of the same sort. *)
  let one = mk_bv_one sortbv8 in
  (* Alternatively, you can create bit-vector value one with: *)
  (* let one = mk_bv_value sortbv8 "1" 2 in *)
  (* let one = mk_bv_value_int sortbv8 1 in *)
  let two = mk_bv_value_int sortbv8 2 in

  (* (bvsdiv x (_ bv2 8)) *)
  let sdiv = mk_term2 Bv_sdiv x two in
  (* (bvashr y (_ bv1 8)) *)
  let ashr = mk_term2 Bv_ashr y one in
  (* ((_ extract 3 0) (bvsdiv x (_ bv2 8))) *)
  let sdive = mk_term1_indexed2 Bv_extract sdiv 3 0 in
  (* ((_ extract 3 0) (bvashr x (_ bv1 8))) *)
  let ashre = mk_term1_indexed2 Bv_extract ashr 3 0 in

  (* (assert *)
  (*     (distinct *)
  (*         ((_ extract 3 0) (bvsdiv x (_ bv2 8))) *)
  (*         ((_ extract 3 0) (bvashr y (_ bv1 8))))) *)
  Solver.assert_formula bitwuzla (mk_term2 Distinct sdive ashre);
  (* (assert (= (f x ((_ extract 6 3) x)) y)) *)
  Solver.assert_formula bitwuzla
    (mk_term2 Equal (mk_term3 Apply f x (mk_term1_indexed2 Bv_extract x 6 3)) y);
  (* (assert (= (select a x) y)) *)
  Solver.assert_formula bitwuzla (mk_term2 Equal (mk_term2 Select a x) y);

After asserting formulas, satisfiability can be determined via check_sat.

  let result = Solver.check_sat bitwuzla in

If the formula is satisfiable and model generation has been enabled, the resulting model can be printed via Solver.get_value and Term.pp. An example implementation illustrating how to print the current model via declared symbols (in this case x, y, f and a) is below:

  Format.open_vbox 0;
  Format.printf "Expect: sat@,";
  Format.printf "Bitwuzla: %s@," (Result.to_string result);
  Format.print_space ();

  (* Print model in SMT-LIBv2 format. *)
  Format.printf "@[<v>Model:@,@[<v 2>(@,%a@]@,)@]"
    (Format.pp_print_list ~pp_sep:Format.pp_print_space (fun ppf term ->
         let sort = Term.sort term in
         Format.fprintf ppf "(define-fun %a ("
           (fun ppf term ->
             try Format.pp_print_string ppf (Term.symbol term)
             with Not_found -> Format.fprintf ppf "%@t%Ld" (Term.id term))
           term;
         if Sort.is_fun sort then (
           let value = Solver.get_value bitwuzla term in
           assert (Term.kind value = Lambda);
           assert (Term.num_children value = 2);
           let rec unroll value =
             let value1 = Term.get value 1 in
             if Term.kind value1 = Lambda then (
               let value0 = Term.get value 0 in
               assert (Term.is_variable value0);
               Format.fprintf ppf "(%a %a) " Term.pp value0 Sort.pp
                 (Term.sort value0);
               unroll value1)
             else value
           in
           let value = unroll value in
           let value0 = Term.get value 0 in
           assert (Term.is_variable value0);
           Format.fprintf ppf "(%a %a)) %a %a)" Term.pp value0 Sort.pp
             (Term.sort value0) Sort.pp (Sort.fun_codomain sort) Term.pp
             (Term.get value 1))
         else
           Format.fprintf ppf ") %a %a)" Sort.pp sort Term.pp
             (Solver.get_value bitwuzla term)))
    [ x; y; f; a ];
  Format.print_space ();
  Format.print_space ();

This will output a possible model, in this case:

(
  (define-fun x () (_ BitVec 8) #b10011111)
  (define-fun y () (_ BitVec 8) #b11111111)
  (define-fun f ((@bzla.var_71 (_ BitVec 8)) (@bzla.var_72 (_ BitVec 4))) 
  (_ BitVec 8) (ite (and (= @bzla.var_71 #b10011111) (= @bzla.var_72 #b0011)) #b11111111 #b00000000))
  (define-fun a () (Array (_ BitVec 8) (_ BitVec 8)) (store ((as const (Array (_ BitVec 8) (_ BitVec 8))) #b00000000) #b10011111 #b11111111))
)

Alternatively, it is possible to query the value of terms as assignment string via Term.value, or as a term via Solver.get_value.

In our case, we can query the assignments of x and y, both bit-vector terms, as binary strings:

  Format.printf "value of x: %s@,"
    (Term.value (String { base = 2 }) (Solver.get_value bitwuzla x));
  Format.printf "value of y: %s@,"
    (Term.value (String { base = 2 }) (Solver.get_value bitwuzla y));
  Format.print_space ();

This will print:

value of x: 10011111
value of y: 11111111

The value of f (a function term) and a (an array term), on the other hand, cannot be represented with a simple type. Thus, function values are given as Lambda, and array values are given as Store. We can retrieve an SMT-LIB2 string representation of the values via Term.pp:

  Format.printf "str() representation of value of x:@,%a@," Term.pp
    (Solver.get_value bitwuzla x);
  Format.printf "str() representation of value of y:@,%a@," Term.pp
    (Solver.get_value bitwuzla y);
  Format.print_space ();

This will print:

str() representation of value of f:
(lambda ((@bzla.var_71 (_ BitVec 8))) (lambda ((@bzla.var_72 (_ BitVec 4))) (ite (and (= @bzla.var_71 #b10011111) (= @bzla.var_72 #b0011)) #b11111111 #b00000000)))
str() representation of value of a:
(store ((as const (Array (_ BitVec 8) (_ BitVec 8))) #b00000000) #b10011111 #b11111111)

Note that the string representation of values representable as simple type (bit-vectors, boolean, floating-point, rounding mode) are given as pure value string (in the given number format) via Term.value. Their string representation retrieved via Term.pp, however, is given in SMT-LIB2 format. For example,

  Format.printf "str() representation of value of x:@,%a@," Term.pp
    (Solver.get_value bitwuzla x);
  Format.printf "str() representation of value of y:@,%a@," Term.pp
    (Solver.get_value bitwuzla y);
  Format.print_space ();

This will print:

str() representation of value of x:
#b10011111
str() representation of value of y:
#b11111111

It is also possible to query the model value of expressions that do not occur in the input formula:

  let v = Solver.get_value bitwuzla (mk_term2 Bv_mul x x) in
  Format.printf "value of v = x * x: %s@," (Term.value (String { base = 2 }) v)

This will print:

value of v = x * x: 11000001

Examples

Other examples together with their SMT-LIB input can be found in directory examples:

  • an incremental example with push and pop (pushpop);

  • an incremental example with check-sat-assuming (checksatassuming);

  • an unsatisfiable example with unsat core generation (unsatcore);

  • an unsatisfiable example with unsat assumption query (unsatassumptions)

  • an example with termination callback (terminator).

Installation

Bitwuzla sources and dependencies are repackaged for convenient use with opam.

From Opam

opam install bitwuzla-cxx

From source

The latest version of ocaml-bitwuzla is available on GitHub: https://github.com/bitwuzla/ocaml-bitwuzla.

:information_source: Dealing with submodules

In order to checkout the complete source tree, run the following at clone time:

git clone --recurse-submodules https://github.com/bitwuzla/ocaml-bitwuzla.git

or at any time:

git submodule init # first time
git submodule update

:warning: Do not download the source archive (.zip, .tar.gz). Download instead the tarball from release panel.

tar -xjf bitwuzla-cxx-0.2.0.tbz
Dependencies

:information_source: Handling dependencies with opam

Dependencies can be automatically installed via opam.

opam pin add -n .                             # read the package definition
opam install --deps-only bitwuzla-cxx             # install OCaml dependencies
opam install --deps-only --with-doc bitwuzla-cxx  # optional, for documentation
opam install --deps-only --with-test bitwuzla-cxx # optional, for tests
Build
dune build @install
Running examples
dune exec -- examples/quickstart.exe # replace quickstart by other examples
Building the API documentation
dune build @doc

An index page containing examples and links to modules can be found in _build/default/_doc/_html/index.html.

Running tests
dune build @runtest

:memo: No output is the expected behavior.

Dependencies (6)

  1. zarith
  2. conf-g++ build
  3. conf-gcc build
  4. conf-git build
  5. ocaml >= "4.12"
  6. dune >= "3.7"

Dev Dependencies (3)

  1. odoc with-doc
  2. ppx_expect with-test & >= "v0.13"
  3. ppx_inline_test with-test & >= "v0.13"

Used by

None

Conflicts

None

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