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test_capi.c
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test_capi.c
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/*++
Copyright (c) 2015 Microsoft Corporation
--*/
#include<stdio.h>
#include<stdlib.h>
#include<stdarg.h>
#include<memory.h>
#include<setjmp.h>
#include<z3.h>
#define LOG_Z3_CALLS
#ifdef LOG_Z3_CALLS
#define LOG_MSG(msg) Z3_append_log(msg)
#else
#define LOG_MSG(msg) ((void)0)
#endif
/**
\defgroup capi_ex C API examples
*/
/**@{*/
/**
@name Auxiliary Functions
*/
/**@{*/
/**
\brief exit gracefully in case of error.
*/
void exitf(const char* message)
{
fprintf(stderr,"BUG: %s.\n", message);
exit(1);
}
/**
\brief exit if unreachable code was reached.
*/
void unreachable()
{
exitf("unreachable code was reached");
}
/**
\brief Simpler error handler.
*/
void error_handler(Z3_context c, Z3_error_code e)
{
printf("Error code: %d\n", e);
exitf("incorrect use of Z3");
}
static jmp_buf g_catch_buffer;
/**
\brief Low tech exceptions.
In high-level programming languages, an error handler can throw an exception.
*/
void throw_z3_error(Z3_context c, Z3_error_code e)
{
longjmp(g_catch_buffer, e);
}
/**
\brief Error handling that depends on checking an error code on the context.
*/
void nothrow_z3_error(Z3_context c, Z3_error_code e) {
// no-op
}
/**
\brief Create a logical context.
Enable model construction. Other configuration parameters can be passed in the cfg variable.
Also enable tracing to stderr and register custom error handler.
*/
Z3_context mk_context_custom(Z3_config cfg, Z3_error_handler err)
{
Z3_context ctx;
Z3_set_param_value(cfg, "model", "true");
ctx = Z3_mk_context(cfg);
Z3_set_error_handler(ctx, err);
return ctx;
}
Z3_solver mk_solver(Z3_context ctx)
{
Z3_solver s = Z3_mk_solver(ctx);
Z3_solver_inc_ref(ctx, s);
return s;
}
void del_solver(Z3_context ctx, Z3_solver s)
{
Z3_solver_dec_ref(ctx, s);
}
/**
\brief Create a logical context.
Enable model construction only.
Also enable tracing to stderr and register standard error handler.
*/
Z3_context mk_context()
{
Z3_config cfg;
Z3_context ctx;
cfg = Z3_mk_config();
ctx = mk_context_custom(cfg, error_handler);
Z3_del_config(cfg);
return ctx;
}
/**
\brief Create a logical context.
Enable fine-grained proof construction.
Enable model construction.
Also enable tracing to stderr and register standard error handler.
*/
Z3_context mk_proof_context() {
Z3_config cfg = Z3_mk_config();
Z3_context ctx;
Z3_set_param_value(cfg, "proof", "true");
ctx = mk_context_custom(cfg, throw_z3_error);
Z3_del_config(cfg);
return ctx;
}
/**
\brief Create a variable using the given name and type.
*/
Z3_ast mk_var(Z3_context ctx, const char * name, Z3_sort ty)
{
Z3_symbol s = Z3_mk_string_symbol(ctx, name);
return Z3_mk_const(ctx, s, ty);
}
/**
\brief Create a boolean variable using the given name.
*/
Z3_ast mk_bool_var(Z3_context ctx, const char * name)
{
Z3_sort ty = Z3_mk_bool_sort(ctx);
return mk_var(ctx, name, ty);
}
/**
\brief Create an integer variable using the given name.
*/
Z3_ast mk_int_var(Z3_context ctx, const char * name)
{
Z3_sort ty = Z3_mk_int_sort(ctx);
return mk_var(ctx, name, ty);
}
/**
\brief Create a string variable using the given name.
*/
Z3_ast mk_string_var(Z3_context ctx, const char * name)
{
Z3_sort ty = Z3_mk_string_sort(ctx);
return mk_var(ctx, name, ty);
}
/**
\brief Create a Z3 integer node using a C int.
*/
Z3_ast mk_int(Z3_context ctx, int v)
{
Z3_sort ty = Z3_mk_int_sort(ctx);
return Z3_mk_int(ctx, v, ty);
}
/**
\brief Create a real variable using the given name.
*/
Z3_ast mk_real_var(Z3_context ctx, const char * name)
{
Z3_sort ty = Z3_mk_real_sort(ctx);
return mk_var(ctx, name, ty);
}
/**
\brief Create the unary function application: <tt>(f x)</tt>.
*/
Z3_ast mk_unary_app(Z3_context ctx, Z3_func_decl f, Z3_ast x)
{
Z3_ast args[1] = {x};
return Z3_mk_app(ctx, f, 1, args);
}
/**
\brief Create the binary function application: <tt>(f x y)</tt>.
*/
Z3_ast mk_binary_app(Z3_context ctx, Z3_func_decl f, Z3_ast x, Z3_ast y)
{
Z3_ast args[2] = {x, y};
return Z3_mk_app(ctx, f, 2, args);
}
/**
\brief Check whether the logical context is satisfiable, and compare the result with the expected result.
If the context is satisfiable, then display the model.
*/
void check(Z3_context ctx, Z3_solver s, Z3_lbool expected_result)
{
Z3_model m = 0;
Z3_lbool result = Z3_solver_check(ctx, s);
switch (result) {
case Z3_L_FALSE:
printf("unsat\n");
break;
case Z3_L_UNDEF:
printf("unknown\n");
m = Z3_solver_get_model(ctx, s);
if (m) Z3_model_inc_ref(ctx, m);
printf("potential model:\n%s\n", Z3_model_to_string(ctx, m));
break;
case Z3_L_TRUE:
m = Z3_solver_get_model(ctx, s);
if (m) Z3_model_inc_ref(ctx, m);
printf("sat\n%s\n", Z3_model_to_string(ctx, m));
break;
}
if (result != expected_result) {
exitf("unexpected result");
}
if (m) Z3_model_dec_ref(ctx, m);
}
/**
\brief Prove that the constraints already asserted into the logical
context implies the given formula. The result of the proof is
displayed.
Z3 is a satisfiability checker. So, one can prove \c f by showing
that <tt>(not f)</tt> is unsatisfiable.
The context \c ctx is not modified by this function.
*/
void prove(Z3_context ctx, Z3_solver s, Z3_ast f, bool is_valid)
{
Z3_model m = 0;
Z3_ast not_f;
/* save the current state of the context */
Z3_solver_push(ctx, s);
not_f = Z3_mk_not(ctx, f);
Z3_solver_assert(ctx, s, not_f);
switch (Z3_solver_check(ctx, s)) {
case Z3_L_FALSE:
/* proved */
printf("valid\n");
if (!is_valid) {
exitf("unexpected result");
}
break;
case Z3_L_UNDEF:
/* Z3 failed to prove/disprove f. */
printf("unknown\n");
m = Z3_solver_get_model(ctx, s);
if (m != 0) {
Z3_model_inc_ref(ctx, m);
/* m should be viewed as a potential counterexample. */
printf("potential counterexample:\n%s\n", Z3_model_to_string(ctx, m));
}
if (is_valid) {
exitf("unexpected result");
}
break;
case Z3_L_TRUE:
/* disproved */
printf("invalid\n");
m = Z3_solver_get_model(ctx, s);
if (m) {
Z3_model_inc_ref(ctx, m);
/* the model returned by Z3 is a counterexample */
printf("counterexample:\n%s\n", Z3_model_to_string(ctx, m));
}
if (is_valid) {
exitf("unexpected result");
}
break;
}
if (m) Z3_model_dec_ref(ctx, m);
/* restore scope */
Z3_solver_pop(ctx, s, 1);
}
/**
\brief Assert the axiom: function f is injective in the i-th argument.
The following axiom is asserted into the logical context:
\code
forall (x_0, ..., x_n) finv(f(x_0, ..., x_i, ..., x_{n-1})) = x_i
\endcode
Where, \c finv is a fresh function declaration.
*/
void assert_inj_axiom(Z3_context ctx, Z3_solver s, Z3_func_decl f, unsigned i)
{
unsigned sz, j;
Z3_sort finv_domain, finv_range;
Z3_func_decl finv;
Z3_sort * types; /* types of the quantified variables */
Z3_symbol * names; /* names of the quantified variables */
Z3_ast * xs; /* arguments for the application f(x_0, ..., x_i, ..., x_{n-1}) */
Z3_ast x_i, fxs, finv_fxs, eq;
Z3_pattern p;
Z3_ast q;
sz = Z3_get_domain_size(ctx, f);
if (i >= sz) {
exitf("failed to create inj axiom");
}
/* declare the i-th inverse of f: finv */
finv_domain = Z3_get_range(ctx, f);
finv_range = Z3_get_domain(ctx, f, i);
finv = Z3_mk_fresh_func_decl(ctx, "inv", 1, &finv_domain, finv_range);
/* allocate temporary arrays */
types = (Z3_sort *) malloc(sizeof(Z3_sort) * sz);
names = (Z3_symbol *) malloc(sizeof(Z3_symbol) * sz);
xs = (Z3_ast *) malloc(sizeof(Z3_ast) * sz);
/* fill types, names and xs */
for (j = 0; j < sz; j++) { types[j] = Z3_get_domain(ctx, f, j); };
for (j = 0; j < sz; j++) { names[j] = Z3_mk_int_symbol(ctx, j); };
for (j = 0; j < sz; j++) { xs[j] = Z3_mk_bound(ctx, j, types[j]); };
x_i = xs[i];
/* create f(x_0, ..., x_i, ..., x_{n-1}) */
fxs = Z3_mk_app(ctx, f, sz, xs);
/* create f_inv(f(x_0, ..., x_i, ..., x_{n-1})) */
finv_fxs = mk_unary_app(ctx, finv, fxs);
/* create finv(f(x_0, ..., x_i, ..., x_{n-1})) = x_i */
eq = Z3_mk_eq(ctx, finv_fxs, x_i);
/* use f(x_0, ..., x_i, ..., x_{n-1}) as the pattern for the quantifier */
p = Z3_mk_pattern(ctx, 1, &fxs);
printf("pattern: %s\n", Z3_pattern_to_string(ctx, p));
printf("\n");
/* create & assert quantifier */
q = Z3_mk_forall(ctx,
0, /* using default weight */
1, /* number of patterns */
&p, /* address of the "array" of patterns */
sz, /* number of quantified variables */
types,
names,
eq);
printf("assert axiom:\n%s\n", Z3_ast_to_string(ctx, q));
Z3_solver_assert(ctx, s, q);
/* free temporary arrays */
free(types);
free(names);
free(xs);
}
/**
\brief Assert the axiom: function f is commutative.
This example uses the SMT-LIB parser to simplify the axiom construction.
*/
void assert_comm_axiom(Z3_context ctx, Z3_solver s, Z3_func_decl f)
{
Z3_sort t;
Z3_symbol f_name, t_name;
Z3_ast_vector q;
unsigned i;
t = Z3_get_range(ctx, f);
if (Z3_get_domain_size(ctx, f) != 2 ||
Z3_get_domain(ctx, f, 0) != t ||
Z3_get_domain(ctx, f, 1) != t) {
exitf("function must be binary, and argument types must be equal to return type");
}
/* Inside the parser, function f will be referenced using the symbol 'f'. */
f_name = Z3_mk_string_symbol(ctx, "f");
/* Inside the parser, type t will be referenced using the symbol 'T'. */
t_name = Z3_mk_string_symbol(ctx, "T");
q = Z3_parse_smtlib2_string(ctx,
"(assert (forall ((x T) (y T)) (= (f x y) (f y x))))",
1, &t_name, &t,
1, &f_name, &f);
printf("assert axiom:\n%s\n", Z3_ast_vector_to_string(ctx, q));
for (i = 0; i < Z3_ast_vector_size(ctx, q); ++i) {
Z3_solver_assert(ctx, s, Z3_ast_vector_get(ctx, q, i));
}
}
/**
\brief Z3 does not support explicitly tuple updates. They can be easily implemented
as macros. The argument \c t must have tuple type.
A tuple update is a new tuple where field \c i has value \c new_val, and all
other fields have the value of the respective field of \c t.
<tt>update(t, i, new_val)</tt> is equivalent to
<tt>mk_tuple(proj_0(t), ..., new_val, ..., proj_n(t))</tt>
*/
Z3_ast mk_tuple_update(Z3_context c, Z3_ast t, unsigned i, Z3_ast new_val)
{
Z3_sort ty;
Z3_func_decl mk_tuple_decl;
unsigned num_fields, j;
Z3_ast * new_fields;
Z3_ast result;
ty = Z3_get_sort(c, t);
if (Z3_get_sort_kind(c, ty) != Z3_DATATYPE_SORT) {
exitf("argument must be a tuple");
}
num_fields = Z3_get_tuple_sort_num_fields(c, ty);
if (i >= num_fields) {
exitf("invalid tuple update, index is too big");
}
new_fields = (Z3_ast*) malloc(sizeof(Z3_ast) * num_fields);
for (j = 0; j < num_fields; j++) {
if (i == j) {
/* use new_val at position i */
new_fields[j] = new_val;
}
else {
/* use field j of t */
Z3_func_decl proj_decl = Z3_get_tuple_sort_field_decl(c, ty, j);
new_fields[j] = mk_unary_app(c, proj_decl, t);
}
}
mk_tuple_decl = Z3_get_tuple_sort_mk_decl(c, ty);
result = Z3_mk_app(c, mk_tuple_decl, num_fields, new_fields);
free(new_fields);
return result;
}
/**
\brief Display a symbol in the given output stream.
*/
void display_symbol(Z3_context c, FILE * out, Z3_symbol s)
{
switch (Z3_get_symbol_kind(c, s)) {
case Z3_INT_SYMBOL:
fprintf(out, "#%d", Z3_get_symbol_int(c, s));
break;
case Z3_STRING_SYMBOL:
fprintf(out, "%s", Z3_get_symbol_string(c, s));
break;
default:
unreachable();
}
}
/**
\brief Display the given type.
*/
void display_sort(Z3_context c, FILE * out, Z3_sort ty)
{
switch (Z3_get_sort_kind(c, ty)) {
case Z3_UNINTERPRETED_SORT:
display_symbol(c, out, Z3_get_sort_name(c, ty));
break;
case Z3_BOOL_SORT:
fprintf(out, "bool");
break;
case Z3_INT_SORT:
fprintf(out, "int");
break;
case Z3_REAL_SORT:
fprintf(out, "real");
break;
case Z3_BV_SORT:
fprintf(out, "bv%d", Z3_get_bv_sort_size(c, ty));
break;
case Z3_ARRAY_SORT:
fprintf(out, "[");
display_sort(c, out, Z3_get_array_sort_domain(c, ty));
fprintf(out, "->");
display_sort(c, out, Z3_get_array_sort_range(c, ty));
fprintf(out, "]");
break;
case Z3_DATATYPE_SORT:
if (Z3_get_datatype_sort_num_constructors(c, ty) != 1)
{
fprintf(out, "%s", Z3_sort_to_string(c,ty));
break;
}
{
unsigned num_fields = Z3_get_tuple_sort_num_fields(c, ty);
unsigned i;
fprintf(out, "(");
for (i = 0; i < num_fields; i++) {
Z3_func_decl field = Z3_get_tuple_sort_field_decl(c, ty, i);
if (i > 0) {
fprintf(out, ", ");
}
display_sort(c, out, Z3_get_range(c, field));
}
fprintf(out, ")");
break;
}
default:
fprintf(out, "unknown[");
display_symbol(c, out, Z3_get_sort_name(c, ty));
fprintf(out, "]");
break;
}
}
/**
\brief Custom ast pretty printer.
This function demonstrates how to use the API to navigate terms.
*/
void display_ast(Z3_context c, FILE * out, Z3_ast v)
{
switch (Z3_get_ast_kind(c, v)) {
case Z3_NUMERAL_AST: {
Z3_sort t;
fprintf(out, "%s", Z3_get_numeral_string(c, v));
t = Z3_get_sort(c, v);
fprintf(out, ":");
display_sort(c, out, t);
break;
}
case Z3_APP_AST: {
unsigned i;
Z3_app app = Z3_to_app(c, v);
unsigned num_fields = Z3_get_app_num_args(c, app);
Z3_func_decl d = Z3_get_app_decl(c, app);
fprintf(out, "%s", Z3_func_decl_to_string(c, d));
if (num_fields > 0) {
fprintf(out, "[");
for (i = 0; i < num_fields; i++) {
if (i > 0) {
fprintf(out, ", ");
}
display_ast(c, out, Z3_get_app_arg(c, app, i));
}
fprintf(out, "]");
}
break;
}
case Z3_QUANTIFIER_AST: {
fprintf(out, "quantifier");
break;
}
default:
fprintf(out, "#unknown");
}
}
/**
\brief Custom function interpretations pretty printer.
*/
void display_function_interpretations(Z3_context c, FILE * out, Z3_model m)
{
unsigned num_functions, i;
fprintf(out, "function interpretations:\n");
num_functions = Z3_model_get_num_funcs(c, m);
for (i = 0; i < num_functions; i++) {
Z3_func_decl fdecl;
Z3_symbol name;
Z3_ast func_else;
unsigned num_entries = 0, j;
Z3_func_interp_opt finterp;
fdecl = Z3_model_get_func_decl(c, m, i);
finterp = Z3_model_get_func_interp(c, m, fdecl);
Z3_func_interp_inc_ref(c, finterp);
name = Z3_get_decl_name(c, fdecl);
display_symbol(c, out, name);
fprintf(out, " = {");
if (finterp)
num_entries = Z3_func_interp_get_num_entries(c, finterp);
for (j = 0; j < num_entries; j++) {
unsigned num_args, k;
Z3_func_entry fentry = Z3_func_interp_get_entry(c, finterp, j);
Z3_func_entry_inc_ref(c, fentry);
if (j > 0) {
fprintf(out, ", ");
}
num_args = Z3_func_entry_get_num_args(c, fentry);
fprintf(out, "(");
for (k = 0; k < num_args; k++) {
if (k > 0) {
fprintf(out, ", ");
}
display_ast(c, out, Z3_func_entry_get_arg(c, fentry, k));
}
fprintf(out, "|->");
display_ast(c, out, Z3_func_entry_get_value(c, fentry));
fprintf(out, ")");
Z3_func_entry_dec_ref(c, fentry);
}
if (num_entries > 0) {
fprintf(out, ", ");
}
fprintf(out, "(else|->");
func_else = Z3_func_interp_get_else(c, finterp);
display_ast(c, out, func_else);
fprintf(out, ")}\n");
Z3_func_interp_dec_ref(c, finterp);
}
}
/**
\brief Custom model pretty printer.
*/
void display_model(Z3_context c, FILE * out, Z3_model m)
{
unsigned num_constants;
unsigned i;
if (!m) return;
num_constants = Z3_model_get_num_consts(c, m);
for (i = 0; i < num_constants; i++) {
Z3_symbol name;
Z3_func_decl cnst = Z3_model_get_const_decl(c, m, i);
Z3_ast a, v;
bool ok;
name = Z3_get_decl_name(c, cnst);
display_symbol(c, out, name);
fprintf(out, " = ");
a = Z3_mk_app(c, cnst, 0, 0);
v = a;
ok = Z3_model_eval(c, m, a, 1, &v);
(void)ok;
display_ast(c, out, v);
fprintf(out, "\n");
}
display_function_interpretations(c, out, m);
}
/**
\brief Similar to #check, but uses #display_model instead of #Z3_model_to_string.
*/
void check2(Z3_context ctx, Z3_solver s, Z3_lbool expected_result)
{
Z3_model m = 0;
Z3_lbool result = Z3_solver_check(ctx, s);
switch (result) {
case Z3_L_FALSE:
printf("unsat\n");
break;
case Z3_L_UNDEF:
printf("unknown\n");
printf("potential model:\n");
m = Z3_solver_get_model(ctx, s);
if (m) Z3_model_inc_ref(ctx, m);
display_model(ctx, stdout, m);
break;
case Z3_L_TRUE:
printf("sat\n");
m = Z3_solver_get_model(ctx, s);
if (m) Z3_model_inc_ref(ctx, m);
display_model(ctx, stdout, m);
break;
}
if (result != expected_result) {
exitf("unexpected result");
}
if (m) Z3_model_dec_ref(ctx, m);
}
/**
\brief Display Z3 version in the standard output.
*/
void display_version()
{
unsigned major, minor, build, revision;
Z3_get_version(&major, &minor, &build, &revision);
printf("Z3 %d.%d.%d.%d\n", major, minor, build, revision);
}
/**@}*/
/**
@name Examples
*/
/**@{*/
/**
\brief "Hello world" example: create a Z3 logical context, and delete it.
*/
void simple_example()
{
Z3_context ctx;
LOG_MSG("simple_example");
printf("\nsimple_example\n");
ctx = mk_context();
/* delete logical context */
Z3_del_context(ctx);
}
/**
Demonstration of how Z3 can be used to prove validity of
De Morgan's Duality Law: {e not(x and y) <-> (not x) or ( not y) }
*/
void demorgan()
{
Z3_config cfg;
Z3_context ctx;
Z3_solver s;
Z3_sort bool_sort;
Z3_symbol symbol_x, symbol_y;
Z3_ast x, y, not_x, not_y, x_and_y, ls, rs, conjecture, negated_conjecture;
Z3_ast args[2];
printf("\nDeMorgan\n");
LOG_MSG("DeMorgan");
cfg = Z3_mk_config();
ctx = Z3_mk_context(cfg);
Z3_del_config(cfg);
bool_sort = Z3_mk_bool_sort(ctx);
symbol_x = Z3_mk_int_symbol(ctx, 0);
symbol_y = Z3_mk_int_symbol(ctx, 1);
x = Z3_mk_const(ctx, symbol_x, bool_sort);
y = Z3_mk_const(ctx, symbol_y, bool_sort);
/* De Morgan - with a negation around */
/* !(!(x && y) <-> (!x || !y)) */
not_x = Z3_mk_not(ctx, x);
not_y = Z3_mk_not(ctx, y);
args[0] = x;
args[1] = y;
x_and_y = Z3_mk_and(ctx, 2, args);
ls = Z3_mk_not(ctx, x_and_y);
args[0] = not_x;
args[1] = not_y;
rs = Z3_mk_or(ctx, 2, args);
conjecture = Z3_mk_iff(ctx, ls, rs);
negated_conjecture = Z3_mk_not(ctx, conjecture);
s = mk_solver(ctx);
Z3_solver_assert(ctx, s, negated_conjecture);
switch (Z3_solver_check(ctx, s)) {
case Z3_L_FALSE:
/* The negated conjecture was unsatisfiable, hence the conjecture is valid */
printf("DeMorgan is valid\n");
break;
case Z3_L_UNDEF:
/* Check returned undef */
printf("Undef\n");
break;
case Z3_L_TRUE:
/* The negated conjecture was satisfiable, hence the conjecture is not valid */
printf("DeMorgan is not valid\n");
break;
}
del_solver(ctx, s);
Z3_del_context(ctx);
}
/**
\brief Find a model for <tt>x xor y</tt>.
*/
void find_model_example1()
{
Z3_context ctx;
Z3_ast x, y, x_xor_y;
Z3_solver s;
printf("\nfind_model_example1\n");
LOG_MSG("find_model_example1");
ctx = mk_context();
s = mk_solver(ctx);
x = mk_bool_var(ctx, "x");
y = mk_bool_var(ctx, "y");
x_xor_y = Z3_mk_xor(ctx, x, y);
Z3_solver_assert(ctx, s, x_xor_y);
printf("model for: x xor y\n");
check(ctx, s, Z3_L_TRUE);
del_solver(ctx, s);
Z3_del_context(ctx);
}
/**
\brief Find a model for <tt>x < y + 1, x > 2</tt>.
Then, assert <tt>not(x = y)</tt>, and find another model.
*/
void find_model_example2()
{
Z3_context ctx;
Z3_ast x, y, one, two, y_plus_one;
Z3_ast x_eq_y;
Z3_ast args[2];
Z3_ast c1, c2, c3;
Z3_solver s;
printf("\nfind_model_example2\n");
LOG_MSG("find_model_example2");
ctx = mk_context();
s = mk_solver(ctx);
x = mk_int_var(ctx, "x");
y = mk_int_var(ctx, "y");
one = mk_int(ctx, 1);
two = mk_int(ctx, 2);
args[0] = y;
args[1] = one;
y_plus_one = Z3_mk_add(ctx, 2, args);
c1 = Z3_mk_lt(ctx, x, y_plus_one);
c2 = Z3_mk_gt(ctx, x, two);
Z3_solver_assert(ctx, s, c1);
Z3_solver_assert(ctx, s, c2);
printf("model for: x < y + 1, x > 2\n");
check(ctx, s, Z3_L_TRUE);
/* assert not(x = y) */
x_eq_y = Z3_mk_eq(ctx, x, y);
c3 = Z3_mk_not(ctx, x_eq_y);
Z3_solver_assert(ctx, s,c3);
printf("model for: x < y + 1, x > 2, not(x = y)\n");
check(ctx, s, Z3_L_TRUE);
del_solver(ctx, s);
Z3_del_context(ctx);
}
/**
\brief Prove <tt>x = y implies g(x) = g(y)</tt>, and
disprove <tt>x = y implies g(g(x)) = g(y)</tt>.
This function demonstrates how to create uninterpreted types and
functions.
*/
void prove_example1()
{
Z3_context ctx;
Z3_solver s;
Z3_symbol U_name, g_name, x_name, y_name;
Z3_sort U;
Z3_sort g_domain[1];
Z3_func_decl g;
Z3_ast x, y, gx, ggx, gy;
Z3_ast eq, f;
printf("\nprove_example1\n");
LOG_MSG("prove_example1");
ctx = mk_context();
s = mk_solver(ctx);
/* create uninterpreted type. */
U_name = Z3_mk_string_symbol(ctx, "U");
U = Z3_mk_uninterpreted_sort(ctx, U_name);
/* declare function g */
g_name = Z3_mk_string_symbol(ctx, "g");
g_domain[0] = U;
g = Z3_mk_func_decl(ctx, g_name, 1, g_domain, U);
/* create x and y */
x_name = Z3_mk_string_symbol(ctx, "x");
y_name = Z3_mk_string_symbol(ctx, "y");
x = Z3_mk_const(ctx, x_name, U);
y = Z3_mk_const(ctx, y_name, U);
/* create g(x), g(y) */
gx = mk_unary_app(ctx, g, x);
gy = mk_unary_app(ctx, g, y);
/* assert x = y */
eq = Z3_mk_eq(ctx, x, y);
Z3_solver_assert(ctx, s, eq);
/* prove g(x) = g(y) */
f = Z3_mk_eq(ctx, gx, gy);
printf("prove: x = y implies g(x) = g(y)\n");
prove(ctx, s, f, true);
/* create g(g(x)) */
ggx = mk_unary_app(ctx, g, gx);
/* disprove g(g(x)) = g(y) */
f = Z3_mk_eq(ctx, ggx, gy);
printf("disprove: x = y implies g(g(x)) = g(y)\n");
prove(ctx, s, f, false);
del_solver(ctx, s);
Z3_del_context(ctx);
}
/**
\brief Prove <tt>not(g(g(x) - g(y)) = g(z)), x + z <= y <= x implies z < 0 </tt>.
Then, show that <tt>z < -1</tt> is not implied.
This example demonstrates how to combine uninterpreted functions and arithmetic.
*/
void prove_example2()
{
Z3_context ctx;
Z3_solver s;
Z3_sort int_sort;
Z3_symbol g_name;
Z3_sort g_domain[1];
Z3_func_decl g;
Z3_ast x, y, z, zero, minus_one, x_plus_z, gx, gy, gz, gx_gy, ggx_gy;
Z3_ast args[2];
Z3_ast eq, c1, c2, c3, f;
printf("\nprove_example2\n");
LOG_MSG("prove_example2");
ctx = mk_context();
s = mk_solver(ctx);
/* declare function g */
int_sort = Z3_mk_int_sort(ctx);
g_name = Z3_mk_string_symbol(ctx, "g");
g_domain[0] = int_sort;
g = Z3_mk_func_decl(ctx, g_name, 1, g_domain, int_sort);
/* create x, y, and z */
x = mk_int_var(ctx, "x");
y = mk_int_var(ctx, "y");
z = mk_int_var(ctx, "z");
/* create gx, gy, gz */
gx = mk_unary_app(ctx, g, x);
gy = mk_unary_app(ctx, g, y);
gz = mk_unary_app(ctx, g, z);
/* create zero */
zero = mk_int(ctx, 0);
/* assert not(g(g(x) - g(y)) = g(z)) */
args[0] = gx;
args[1] = gy;
gx_gy = Z3_mk_sub(ctx, 2, args);
ggx_gy = mk_unary_app(ctx, g, gx_gy);
eq = Z3_mk_eq(ctx, ggx_gy, gz);
c1 = Z3_mk_not(ctx, eq);
Z3_solver_assert(ctx, s, c1);
/* assert x + z <= y */
args[0] = x;
args[1] = z;
x_plus_z = Z3_mk_add(ctx, 2, args);
c2 = Z3_mk_le(ctx, x_plus_z, y);
Z3_solver_assert(ctx, s, c2);
/* assert y <= x */
c3 = Z3_mk_le(ctx, y, x);
Z3_solver_assert(ctx, s, c3);
/* prove z < 0 */
f = Z3_mk_lt(ctx, z, zero);
printf("prove: not(g(g(x) - g(y)) = g(z)), x + z <= y <= x implies z < 0\n");
prove(ctx, s, f, true);
/* disprove z < -1 */
minus_one = mk_int(ctx, -1);
f = Z3_mk_lt(ctx, z, minus_one);
printf("disprove: not(g(g(x) - g(y)) = g(z)), x + z <= y <= x implies z < -1\n");
prove(ctx, s, f, false);
del_solver(ctx, s);