/*++
Copyright (c) 2012 Microsoft Corporation
Thin C++ layer on top of the Z3 C API.
Main features:
- Smart pointers for all Z3 objects.
- Object-Oriented interface.
- Operator overloading.
- Exceptions for signining Z3 errors
The C API can be used simultaneously with the C++ layer.
However, if you use the C API directly, you will have to check the error conditions manually.
Of course, you can invoke the method check_error() of the context object.
Author:
Leonardo (leonardo) 2012-03-28
Notes:
--*/
#ifndef __Z3PP_H_
#define __Z3PP_H_
#include<cassert>
#include<iostream>
#include<string>
#include<sstream>
#include<z3.h>
#include<limits.h>
namespace z3 {
class exception;
class config;
class context;
class symbol;
class params;
class ast;
class sort;
class func_decl;
class expr;
class solver;
class goal;
class tactic;
class probe;
class model;
class func_interp;
class func_entry;
class statistics;
class apply_result;
class fixedpoint;
/**
\brief Exception used to sign API usage errors.
*/
class exception {
std::string m_msg;
public:
exception(char const * msg):m_msg(msg) {}
char const * msg() const { return m_msg.c_str(); }
friend std::ostream & operator<<(std::ostream & out, exception const & e) { out << e.msg(); return out; }
};
/**
\brief Z3 global configuration object.
*/
class config {
Z3_config m_cfg;
config(config const & s);
config & operator=(config const & s);
public:
config() { m_cfg = Z3_mk_config(); }
~config() { Z3_del_config(m_cfg); }
operator Z3_config() const { return m_cfg; }
/**
\brief Add a global configuration.
*/
void set(char const * param, char const * value) { Z3_set_param_value(m_cfg, param, value); }
void set(char const * param, bool value) { Z3_set_param_value(m_cfg, param, value ? "true" : "false"); }
void set(char const * param, int value) {
std::ostringstream oss;
oss << value;
Z3_set_param_value(m_cfg, param, oss.str().c_str());
}
};
/**
\brief A Context manages all other Z3 objects, global configuration options, etc.
*/
class context {
Z3_context m_ctx;
static void error_handler(Z3_context c, Z3_error_code e) { /* do nothing */ }
void init(config & c) {
m_ctx = Z3_mk_context_rc(c);
Z3_set_error_handler(m_ctx, error_handler);
Z3_set_ast_print_mode(m_ctx, Z3_PRINT_SMTLIB2_COMPLIANT);
}
context(context const & s);
context & operator=(context const & s);
public:
context() { config c; init(c); }
context(config & c) { init(c); }
~context() { Z3_del_context(m_ctx); }
operator Z3_context() const { return m_ctx; }
/**
\brief Auxiliary method used to check for API usage errors.
*/
void check_error() const {
Z3_error_code e = Z3_get_error_code(m_ctx);
if (e != Z3_OK)
throw exception(Z3_get_error_msg_ex(m_ctx, e));
}
void set(char const * param, char const * value) { Z3_update_param_value(m_ctx, param, value); }
void set(char const * param, bool value) { Z3_update_param_value(m_ctx, param, value ? "true" : "false"); }
void set(char const * param, int value) {
std::ostringstream oss;
oss << value;
Z3_update_param_value(m_ctx, param, oss.str().c_str());
}
void interrupt() { Z3_interrupt(m_ctx); }
symbol str_symbol(char const * s);
symbol int_symbol(int n);
sort bool_sort();
sort int_sort();
sort real_sort();
sort bv_sort(unsigned sz);
sort array_sort(sort d, sort r);
func_decl function(symbol const & name, unsigned arity, sort const * domain, sort const & range);
func_decl function(char const * name, unsigned arity, sort const * domain, sort const & range);
func_decl function(char const * name, sort const & domain, sort const & range);
func_decl function(char const * name, sort const & d1, sort const & d2, sort const & range);
func_decl function(char const * name, sort const & d1, sort const & d2, sort const & d3, sort const & range);
func_decl function(char const * name, sort const & d1, sort const & d2, sort const & d3, sort const & d4, sort const & range);
func_decl function(char const * name, sort const & d1, sort const & d2, sort const & d3, sort const & d4, sort const & d5, sort const & range);
expr constant(symbol const & name, sort const & s);
expr constant(char const * name, sort const & s);
expr bool_const(char const * name);
expr int_const(char const * name);
expr real_const(char const * name);
expr bv_const(char const * name, unsigned sz);
expr bool_val(bool b);
expr int_val(int n);
expr int_val(unsigned n);
expr int_val(__int64 n);
expr int_val(__uint64 n);
expr int_val(char const * n);
expr real_val(int n, int d);
expr real_val(int n);
expr real_val(unsigned n);
expr real_val(__int64 n);
expr real_val(__uint64 n);
expr real_val(char const * n);
expr bv_val(int n, unsigned sz);
expr bv_val(unsigned n, unsigned sz);
expr bv_val(__int64 n, unsigned sz);
expr bv_val(__uint64 n, unsigned sz);
expr bv_val(char const * n, unsigned sz);
expr num_val(int n, sort const & s);
};
template<typename T>
class array {
T * m_array;
unsigned m_size;
array(array const & s);
array & operator=(array const & s);
public:
array(unsigned sz):m_size(sz) { m_array = new T[sz]; }
~array() { delete[] m_array; }
unsigned size() const { return m_size; }
T & operator[](unsigned i) { assert(i < m_size); return m_array[i]; }
T const & operator[](unsigned i) const { assert(i < m_size); return m_array[i]; }
T const * ptr() const { return m_array; }
T * ptr() { return m_array; }
};
class object {
protected:
context * m_ctx;
public:
object(context & c):m_ctx(&c) {}
object(object const & s):m_ctx(s.m_ctx) {}
context & ctx() const { return *m_ctx; }
void check_error() const { m_ctx->check_error(); }
friend void check_context(object const & a, object const & b) { assert(a.m_ctx == b.m_ctx); }
};
class symbol : public object {
Z3_symbol m_sym;
public:
symbol(context & c, Z3_symbol s):object(c), m_sym(s) {}
symbol(symbol const & s):object(s), m_sym(s.m_sym) {}
symbol & operator=(symbol const & s) { m_ctx = s.m_ctx; m_sym = s.m_sym; return *this; }
operator Z3_symbol() const { return m_sym; }
Z3_symbol_kind kind() const { return Z3_get_symbol_kind(ctx(), m_sym); }
std::string str() const { assert(kind() == Z3_STRING_SYMBOL); return Z3_get_symbol_string(ctx(), m_sym); }
int to_int() const { assert(kind() == Z3_INT_SYMBOL); return Z3_get_symbol_int(ctx(), m_sym); }
friend std::ostream & operator<<(std::ostream & out, symbol const & s) {
if (s.kind() == Z3_INT_SYMBOL)
out << "k!" << s.to_int();
else
out << s.str().c_str();
return out;
}
};
class params : public object {
Z3_params m_params;
public:
params(context & c):object(c) { m_params = Z3_mk_params(c); Z3_params_inc_ref(ctx(), m_params); }
params(params const & s):object(s), m_params(s.m_params) { Z3_params_inc_ref(ctx(), m_params); }
~params() { Z3_params_dec_ref(ctx(), m_params); }
operator Z3_params() const { return m_params; }
params & operator=(params const & s) {
Z3_params_inc_ref(s.ctx(), s.m_params);
Z3_params_dec_ref(ctx(), m_params);
m_ctx = s.m_ctx;
m_params = s.m_params;
return *this;
}
void set(char const * k, bool b) { Z3_params_set_bool(ctx(), m_params, ctx().str_symbol(k), b); }
void set(char const * k, unsigned n) { Z3_params_set_uint(ctx(), m_params, ctx().str_symbol(k), n); }
void set(char const * k, double n) { Z3_params_set_double(ctx(), m_params, ctx().str_symbol(k), n); }
void set(char const * k, symbol const & s) { Z3_params_set_symbol(ctx(), m_params, ctx().str_symbol(k), s); }
friend std::ostream & operator<<(std::ostream & out, params const & p) { out << Z3_params_to_string(p.ctx(), p); return out; }
};
class ast : public object {
protected:
Z3_ast m_ast;
public:
ast(context & c):object(c), m_ast(0) {}
ast(context & c, Z3_ast n):object(c), m_ast(n) { Z3_inc_ref(ctx(), m_ast); }
ast(ast const & s):object(s), m_ast(s.m_ast) { Z3_inc_ref(ctx(), m_ast); }
~ast() { if (m_ast) Z3_dec_ref(*m_ctx, m_ast); }
operator Z3_ast() const { return m_ast; }
operator bool() const { return m_ast != 0; }
ast & operator=(ast const & s) { Z3_inc_ref(s.ctx(), s.m_ast); if (m_ast) Z3_dec_ref(ctx(), m_ast); m_ctx = s.m_ctx; m_ast = s.m_ast; return *this; }
Z3_ast_kind kind() const { Z3_ast_kind r = Z3_get_ast_kind(ctx(), m_ast); check_error(); return r; }
unsigned hash() const { unsigned r = Z3_get_ast_hash(ctx(), m_ast); check_error(); return r; }
friend std::ostream & operator<<(std::ostream & out, ast const & n) { out << Z3_ast_to_string(n.ctx(), n.m_ast); return out; }
/**
\brief Return true if the ASTs are structurally identical.
*/
friend bool eq(ast const & a, ast const & b) { return Z3_is_eq_ast(a.ctx(), a, b) != 0; }
};
class sort : public ast {
public:
sort(context & c):ast(c) {}
sort(context & c, Z3_sort s):ast(c, reinterpret_cast<Z3_ast>(s)) {}
sort(sort const & s):ast(s) {}
operator Z3_sort() const { return reinterpret_cast<Z3_sort>(m_ast); }
sort & operator=(sort const & s) { return static_cast<sort&>(ast::operator=(s)); }
Z3_sort_kind sort_kind() const { return Z3_get_sort_kind(*m_ctx, *this); }
bool is_bool() const { return sort_kind() == Z3_BOOL_SORT; }
bool is_int() const { return sort_kind() == Z3_INT_SORT; }
bool is_real() const { return sort_kind() == Z3_REAL_SORT; }
bool is_arith() const { return is_int() || is_real(); }
bool is_bv() const { return sort_kind() == Z3_BV_SORT; }
bool is_array() const { return sort_kind() == Z3_ARRAY_SORT; }
bool is_datatype() const { return sort_kind() == Z3_DATATYPE_SORT; }
bool is_relation() const { return sort_kind() == Z3_RELATION_SORT; }
bool is_finite_domain() const { return sort_kind() == Z3_FINITE_DOMAIN_SORT; }
unsigned bv_size() const { assert(is_bv()); unsigned r = Z3_get_bv_sort_size(ctx(), *this); check_error(); return r; }
sort array_domain() const { assert(is_array()); Z3_sort s = Z3_get_array_sort_domain(ctx(), *this); check_error(); return sort(ctx(), s); }
sort array_range() const { assert(is_array()); Z3_sort s = Z3_get_array_sort_range(ctx(), *this); check_error(); return sort(ctx(), s); }
};
class func_decl : public ast {
public:
func_decl(context & c):ast(c) {}
func_decl(context & c, Z3_func_decl n):ast(c, reinterpret_cast<Z3_ast>(n)) {}
func_decl(func_decl const & s):ast(s) {}
operator Z3_func_decl() const { return reinterpret_cast<Z3_func_decl>(m_ast); }
func_decl & operator=(func_decl const & s) { return static_cast<func_decl&>(ast::operator=(s)); }
unsigned arity() const { return Z3_get_arity(ctx(), *this); }
sort domain(unsigned i) const { assert(i < arity()); Z3_sort r = Z3_get_domain(ctx(), *this, i); check_error(); return sort(ctx(), r); }
sort range() const { Z3_sort r = Z3_get_range(ctx(), *this); check_error(); return sort(ctx(), r); }
symbol name() const { Z3_symbol s = Z3_get_decl_name(ctx(), *this); check_error(); return symbol(ctx(), s); }
Z3_decl_kind decl_kind() const { return Z3_get_decl_kind(ctx(), *this); }
bool is_const() const { return arity() == 0; }
expr operator()(unsigned n, expr const * args) const;
expr operator()(expr const & a) const;
expr operator()(int a) const;
expr operator()(expr const & a1, expr const & a2) const;
expr operator()(expr const & a1, int a2) const;
expr operator()(int a1, expr const & a2) const;
expr operator()(expr const & a1, expr const & a2, expr const & a3) const;
expr operator()(expr const & a1, expr const & a2, expr const & a3, expr const & a4) const;
expr operator()(expr const & a1, expr const & a2, expr const & a3, expr const & a4, expr const & a5) const;
};
class expr : public ast {
public:
expr(context & c):ast(c) {}
expr(context & c, Z3_ast n):ast(c, reinterpret_cast<Z3_ast>(n)) {}
expr(expr const & n):ast(n) {}
expr & operator=(expr const & n) { return static_cast<expr&>(ast::operator=(n)); }
sort get_sort() const { Z3_sort s = Z3_get_sort(*m_ctx, m_ast); check_error(); return sort(*m_ctx, s); }
bool is_bool() const { return get_sort().is_bool(); }
bool is_int() const { return get_sort().is_int(); }
bool is_real() const { return get_sort().is_real(); }
bool is_arith() const { return get_sort().is_arith(); }
bool is_bv() const { return get_sort().is_bv(); }
bool is_array() const { return get_sort().is_array(); }
bool is_datatype() const { return get_sort().is_datatype(); }
bool is_relation() const { return get_sort().is_relation(); }
bool is_finite_domain() const { return get_sort().is_finite_domain(); }
bool is_numeral() const { return kind() == Z3_NUMERAL_AST; }
bool is_app() const { return kind() == Z3_APP_AST || kind() == Z3_NUMERAL_AST; }
bool is_quantifier() const { return kind() == Z3_QUANTIFIER_AST; }
bool is_var() const { return kind() == Z3_VAR_AST; }
bool is_well_sorted() const { bool r = Z3_is_well_sorted(ctx(), m_ast) != 0; check_error(); return r; }
operator Z3_app() const { assert(is_app()); return reinterpret_cast<Z3_app>(m_ast); }
func_decl decl() const { Z3_func_decl f = Z3_get_app_decl(ctx(), *this); check_error(); return func_decl(ctx(), f); }
unsigned num_args() const { unsigned r = Z3_get_app_num_args(ctx(), *this); check_error(); return r; }
expr arg(unsigned i) const { Z3_ast r = Z3_get_app_arg(ctx(), *this, i); check_error(); return expr(ctx(), r); }
expr body() const { assert(is_quantifier()); Z3_ast r = Z3_get_quantifier_body(ctx(), *this); check_error(); return expr(ctx(), r); }
friend expr operator!(expr const & a) {
assert(a.is_bool());
Z3_ast r = Z3_mk_not(a.ctx(), a);
a.check_error();
return expr(a.ctx(), r);
}
friend expr operator&&(expr const & a, expr const & b) {
check_context(a, b);
assert(a.is_bool() && b.is_bool());
Z3_ast args[2] = { a, b };
Z3_ast r = Z3_mk_and(a.ctx(), 2, args);
a.check_error();
return expr(a.ctx(), r);
}
friend expr operator&&(expr const & a, bool b) { return a && a.ctx().bool_val(b); }
friend expr operator&&(bool a, expr const & b) { return b.ctx().bool_val(a) && b; }
friend expr operator||(expr const & a, expr const & b) {
check_context(a, b);
assert(a.is_bool() && b.is_bool());
Z3_ast args[2] = { a, b };
Z3_ast r = Z3_mk_or(a.ctx(), 2, args);
a.check_error();
return expr(a.ctx(), r);
}
friend expr operator||(expr const & a, bool b) { return a || a.ctx().bool_val(b); }
friend expr operator||(bool a, expr const & b) { return b.ctx().bool_val(a) || b; }
friend expr implies(expr const & a, expr const & b) {
check_context(a, b);
assert(a.is_bool() && b.is_bool());
Z3_ast r = Z3_mk_implies(a.ctx(), a, b);
a.check_error();
return expr(a.ctx(), r);
}
friend expr operator==(expr const & a, expr const & b) {
check_context(a, b);
Z3_ast r = Z3_mk_eq(a.ctx(), a, b);
a.check_error();
return expr(a.ctx(), r);
}
friend expr operator==(expr const & a, int b) { assert(a.is_arith() || a.is_bv()); return a == a.ctx().num_val(b, a.get_sort()); }
friend expr operator==(int a, expr const & b) { assert(b.is_arith() || b.is_bv()); return b.ctx().num_val(a, b.get_sort()) == b; }
friend expr operator!=(expr const & a, expr const & b) {
check_context(a, b);
Z3_ast args[2] = { a, b };
Z3_ast r = Z3_mk_distinct(a.ctx(), 2, args);
a.check_error();
return expr(a.ctx(), r);
}
friend expr operator!=(expr const & a, int b) { assert(a.is_arith() || a.is_bv()); return a != a.ctx().num_val(b, a.get_sort()); }
friend expr operator!=(int a, expr const & b) { assert(b.is_arith() || b.is_bv()); return b.ctx().num_val(a, b.get_sort()) != b; }
friend expr operator+(expr const & a, expr const & b) {
check_context(a, b);
Z3_ast r;
if (a.is_arith() && b.is_arith()) {
Z3_ast args[2] = { a, b };
r = Z3_mk_add(a.ctx(), 2, args);
}
else if (a.is_bv() && b.is_bv()) {
r = Z3_mk_bvadd(a.ctx(), a, b);
}
else {
// operator is not supported by given arguments.
assert(false);
}
a.check_error();
return expr(a.ctx(), r);
}
friend expr operator+(expr const & a, int b) { return a + a.ctx().num_val(b, a.get_sort()); }
friend expr operator+(int a, expr const & b) { return b.ctx().num_val(a, b.get_sort()) + b; }
friend expr operator*(expr const & a, expr const & b) {
check_context(a, b);
Z3_ast r;
if (a.is_arith() && b.is_arith()) {
Z3_ast args[2] = { a, b };
r = Z3_mk_mul(a.ctx(), 2, args);
}
else if (a.is_bv() && b.is_bv()) {
r = Z3_mk_bvmul(a.ctx(), a, b);
}
else {
// operator is not supported by given arguments.
assert(false);
}
a.check_error();
return expr(a.ctx(), r);
}
friend expr operator*(expr const & a, int b) { return a * a.ctx().num_val(b, a.get_sort()); }
friend expr operator*(int a, expr const & b) { return b.ctx().num_val(a, b.get_sort()) * b; }
/**
\brief Power operator
*/
friend expr pw(expr const & a, expr const & b) {
assert(a.is_arith() && b.is_arith());
check_context(a, b);
Z3_ast r = Z3_mk_power(a.ctx(), a, b);
a.check_error();
return expr(a.ctx(), r);
}
friend expr pw(expr const & a, int b) { return pw(a, a.ctx().num_val(b, a.get_sort())); }
friend expr pw(int a, expr const & b) { return pw(b.ctx().num_val(a, b.get_sort()), b); }
friend expr operator/(expr const & a, expr const & b) {
check_context(a, b);
Z3_ast r;
if (a.is_arith() && b.is_arith()) {
r = Z3_mk_div(a.ctx(), a, b);
}
else if (a.is_bv() && b.is_bv()) {
r = Z3_mk_bvsdiv(a.ctx(), a, b);
}
else {
// operator is not supported by given arguments.
assert(false);
}
a.check_error();
return expr(a.ctx(), r);
}
friend expr operator/(expr const & a, int b) { return a / a.ctx().num_val(b, a.get_sort()); }
friend expr operator/(int a, expr const & b) { return b.ctx().num_val(a, b.get_sort()) / b; }
friend expr operator-(expr const & a) {
Z3_ast r;
if (a.is_arith()) {
r = Z3_mk_unary_minus(a.ctx(), a);
}
else if (a.is_bv()) {
r = Z3_mk_bvneg(a.ctx(), a);
}
else {
// operator is not supported by given arguments.
assert(false);
}
a.check_error();
return expr(a.ctx(), r);
}
friend expr operator-(expr const & a, expr const & b) {
check_context(a, b);
Z3_ast r;
if (a.is_arith() && b.is_arith()) {
Z3_ast args[2] = { a, b };
r = Z3_mk_sub(a.ctx(), 2, args);
}
else if (a.is_bv() && b.is_bv()) {
r = Z3_mk_bvsub(a.ctx(), a, b);
}
else {
// operator is not supported by given arguments.
assert(false);
}
a.check_error();
return expr(a.ctx(), r);
}
friend expr operator-(expr const & a, int b) { return a - a.ctx().num_val(b, a.get_sort()); }
friend expr operator-(int a, expr const & b) { return b.ctx().num_val(a, b.get_sort()) - a; }
friend expr operator<=(expr const & a, expr const & b) {
check_context(a, b);
Z3_ast r;
if (a.is_arith() && b.is_arith()) {
r = Z3_mk_le(a.ctx(), a, b);
}
else if (a.is_bv() && b.is_bv()) {
r = Z3_mk_bvsle(a.ctx(), a, b);
}
else {
// operator is not supported by given arguments.
assert(false);
}
a.check_error();
return expr(a.ctx(), r);
}
friend expr operator<=(expr const & a, int b) { return a <= a.ctx().num_val(b, a.get_sort()); }
friend expr operator<=(int a, expr const & b) { return b.ctx().num_val(a, b.get_sort()) <= a; }
friend expr operator>=(expr const & a, expr const & b) {
check_context(a, b);
Z3_ast r;
if (a.is_arith() && b.is_arith()) {
r = Z3_mk_ge(a.ctx(), a, b);
}
else if (a.is_bv() && b.is_bv()) {
r = Z3_mk_bvsge(a.ctx(), a, b);
}
else {
// operator is not supported by given arguments.
assert(false);
}
a.check_error();
return expr(a.ctx(), r);
}
friend expr operator>=(expr const & a, int b) { return a >= a.ctx().num_val(b, a.get_sort()); }
friend expr operator>=(int a, expr const & b) { return b.ctx().num_val(a, b.get_sort()) >= a; }
friend expr operator<(expr const & a, expr const & b) {
check_context(a, b);
Z3_ast r;
if (a.is_arith() && b.is_arith()) {
r = Z3_mk_lt(a.ctx(), a, b);
}
else if (a.is_bv() && b.is_bv()) {
r = Z3_mk_bvslt(a.ctx(), a, b);
}
else {
// operator is not supported by given arguments.
assert(false);
}
a.check_error();
return expr(a.ctx(), r);
}
friend expr operator<(expr const & a, int b) { return a < a.ctx().num_val(b, a.get_sort()); }
friend expr operator<(int a, expr const & b) { return b.ctx().num_val(a, b.get_sort()) < a; }
friend expr operator>(expr const & a, expr const & b) {
check_context(a, b);
Z3_ast r;
if (a.is_arith() && b.is_arith()) {
r = Z3_mk_gt(a.ctx(), a, b);
}
else if (a.is_bv() && b.is_bv()) {
r = Z3_mk_bvsgt(a.ctx(), a, b);
}
else {
// operator is not supported by given arguments.
assert(false);
}
a.check_error();
return expr(a.ctx(), r);
}
friend expr operator>(expr const & a, int b) { return a > a.ctx().num_val(b, a.get_sort()); }
friend expr operator>(int a, expr const & b) { return b.ctx().num_val(a, b.get_sort()) > a; }
friend expr operator&(expr const & a, expr const & b) { check_context(a, b); Z3_ast r = Z3_mk_bvand(a.ctx(), a, b); return expr(a.ctx(), r); }
friend expr operator&(expr const & a, int b) { return a & a.ctx().num_val(b, a.get_sort()); }
friend expr operator&(int a, expr const & b) { return b.ctx().num_val(a, b.get_sort()) & b; }
friend expr operator^(expr const & a, expr const & b) { check_context(a, b); Z3_ast r = Z3_mk_bvxor(a.ctx(), a, b); return expr(a.ctx(), r); }
friend expr operator^(expr const & a, int b) { return a ^ a.ctx().num_val(b, a.get_sort()); }
friend expr operator^(int a, expr const & b) { return b.ctx().num_val(a, b.get_sort()) ^ b; }
friend expr operator|(expr const & a, expr const & b) { check_context(a, b); Z3_ast r = Z3_mk_bvor(a.ctx(), a, b); return expr(a.ctx(), r); }
friend expr operator|(expr const & a, int b) { return a | a.ctx().num_val(b, a.get_sort()); }
friend expr operator|(int a, expr const & b) { return b.ctx().num_val(a, b.get_sort()) | b; }
friend expr operator~(expr const & a) { Z3_ast r = Z3_mk_bvnot(a.ctx(), a); return expr(a.ctx(), r); }
expr simplify() const { Z3_ast r = Z3_simplify(ctx(), m_ast); check_error(); return expr(ctx(), r); }
expr simplify(params const & p) const { Z3_ast r = Z3_simplify_ex(ctx(), m_ast, p); check_error(); return expr(ctx(), r); }
};
/**
\brief Wraps a Z3_ast as an expr object. It also checks for errors.
This function allows the user to use the whole C API with the C++ layer defined in this file.
*/
inline expr to_expr(context & c, Z3_ast a) {
c.check_error();
assert(Z3_get_ast_kind(c, a) == Z3_APP_AST ||
Z3_get_ast_kind(c, a) == Z3_NUMERAL_AST ||
Z3_get_ast_kind(c, a) == Z3_VAR_AST ||
Z3_get_ast_kind(c, a) == Z3_QUANTIFIER_AST);
return expr(c, a);
}
inline sort to_sort(context & c, Z3_sort s) {
c.check_error();
return sort(c, s);
}
inline func_decl to_func_decl(context & c, Z3_func_decl f) {
c.check_error();
return func_decl(c, f);
}
/**
\brief unsigned less than or equal to operator for bitvectors.
*/
inline expr ule(expr const & a, expr const & b) { return to_expr(a.ctx(), Z3_mk_bvule(a.ctx(), a, b)); }
inline expr ule(expr const & a, int b) { return ule(a, a.ctx().num_val(b, a.get_sort())); }
inline expr ule(int a, expr const & b) { return ule(b.ctx().num_val(a, b.get_sort()), a); }
/**
\brief unsigned less than operator for bitvectors.
*/
inline expr ult(expr const & a, expr const & b) { return to_expr(a.ctx(), Z3_mk_bvult(a.ctx(), a, b)); }
inline expr ult(expr const & a, int b) { return ult(a, a.ctx().num_val(b, a.get_sort())); }
inline expr ult(int a, expr const & b) { return ult(b.ctx().num_val(a, b.get_sort()), a); }
/**
\brief unsigned greater than or equal to operator for bitvectors.
*/
inline expr uge(expr const & a, expr const & b) { return to_expr(a.ctx(), Z3_mk_bvuge(a.ctx(), a, b)); }
inline expr uge(expr const & a, int b) { return uge(a, a.ctx().num_val(b, a.get_sort())); }
inline expr uge(int a, expr const & b) { return uge(b.ctx().num_val(a, b.get_sort()), a); }
/**
\brief unsigned greater than operator for bitvectors.
*/
inline expr ugt(expr const & a, expr const & b) { return to_expr(a.ctx(), Z3_mk_bvugt(a.ctx(), a, b)); }
inline expr ugt(expr const & a, int b) { return ugt(a, a.ctx().num_val(b, a.get_sort())); }
inline expr ugt(int a, expr const & b) { return ugt(b.ctx().num_val(a, b.get_sort()), a); }
/**
\brief unsigned division operator for bitvectors.
*/
inline expr udiv(expr const & a, expr const & b) { return to_expr(a.ctx(), Z3_mk_bvudiv(a.ctx(), a, b)); }
inline expr udiv(expr const & a, int b) { return udiv(a, a.ctx().num_val(b, a.get_sort())); }
inline expr udiv(int a, expr const & b) { return udiv(b.ctx().num_val(a, b.get_sort()), a); }
template<typename T> class cast_ast;
template<> class cast_ast<ast> {
public:
ast operator()(context & c, Z3_ast a) { return ast(c, a); }
};
template<> class cast_ast<expr> {
public:
expr operator()(context & c, Z3_ast a) {
assert(Z3_get_ast_kind(c, a) == Z3_NUMERAL_AST ||
Z3_get_ast_kind(c, a) == Z3_APP_AST ||
Z3_get_ast_kind(c, a) == Z3_QUANTIFIER_AST ||
Z3_get_ast_kind(c, a) == Z3_VAR_AST);
return expr(c, a);
}
};
template<> class cast_ast<sort> {
public:
sort operator()(context & c, Z3_ast a) {
assert(Z3_get_ast_kind(c, a) == Z3_SORT_AST);
return sort(c, reinterpret_cast<Z3_sort>(a));
}
};
template<> class cast_ast<func_decl> {
public:
func_decl operator()(context & c, Z3_ast a) {
assert(Z3_get_ast_kind(c, a) == Z3_FUNC_DECL_AST);
return func_decl(c, reinterpret_cast<Z3_func_decl>(a));
}
};
template<typename T>
class ast_vector_tpl : public object {
Z3_ast_vector m_vector;
void init(Z3_ast_vector v) { Z3_ast_vector_inc_ref(ctx(), v); m_vector = v; }
public:
ast_vector_tpl(context & c):object(c) { init(Z3_mk_ast_vector(c)); }
ast_vector_tpl(context & c, Z3_ast_vector v):object(c) { init(v); }
ast_vector_tpl(ast_vector_tpl const & s):object(s), m_vector(s.m_vector) { Z3_ast_vector_inc_ref(ctx(), m_vector); }
~ast_vector_tpl() { Z3_ast_vector_dec_ref(ctx(), m_vector); }
operator Z3_ast_vector() const { return m_vector; }
unsigned size() const { return Z3_ast_vector_size(ctx(), m_vector); }
T operator[](unsigned i) const { Z3_ast r = Z3_ast_vector_get(ctx(), m_vector, i); check_error(); return cast_ast<T>()(ctx(), r); }
void push_back(T const & e) { Z3_ast_vector_push(ctx(), m_vector, e); check_error(); }
void resize(unsigned sz) { Z3_ast_vector_resize(ctx(), m_vector, sz); check_error(); }
T back() const { return operator[](size() - 1); }
void pop_back() { assert(size() > 0); resize(size() - 1); }
bool empty() const { return size() == 0; }
ast_vector_tpl & operator=(ast_vector_tpl const & s) {
Z3_ast_vector_inc_ref(s.ctx(), s.m_vector);
Z3_ast_vector_dec_ref(ctx(), m_vector);
m_ctx = s.m_ctx;
m_vector = s.m_vector;
return *this;
}
friend std::ostream & operator<<(std::ostream & out, ast_vector_tpl const & v) { out << Z3_ast_vector_to_string(v.ctx(), v); return out; }
};
typedef ast_vector_tpl<ast> ast_vector;
typedef ast_vector_tpl<expr> expr_vector;
typedef ast_vector_tpl<sort> sort_vector;
typedef ast_vector_tpl<func_decl> func_decl_vector;
class func_entry : public object {
Z3_func_entry m_entry;
void init(Z3_func_entry e) {
m_entry = e;
Z3_func_entry_inc_ref(ctx(), m_entry);
}
public:
func_entry(context & c, Z3_func_entry e):object(c) { init(e); }
func_entry(func_entry const & s):object(s) { init(s.m_entry); }
~func_entry() { Z3_func_entry_dec_ref(ctx(), m_entry); }
operator Z3_func_entry() const { return m_entry; }
func_entry & operator=(func_entry const & s) {
Z3_func_entry_inc_ref(s.ctx(), s.m_entry);
Z3_func_entry_dec_ref(ctx(), m_entry);
m_ctx = s.m_ctx;
m_entry = s.m_entry;
return *this;
}
expr value() const { Z3_ast r = Z3_func_entry_get_value(ctx(), m_entry); check_error(); return expr(ctx(), r); }
unsigned num_args() const { unsigned r = Z3_func_entry_get_num_args(ctx(), m_entry); check_error(); return r; }
expr arg(unsigned i) const { Z3_ast r = Z3_func_entry_get_arg(ctx(), m_entry, i); check_error(); return expr(ctx(), r); }
};
class func_interp : public object {
Z3_func_interp m_interp;
void init(Z3_func_interp e) {
m_interp = e;
Z3_func_interp_inc_ref(ctx(), m_interp);
}
public:
func_interp(context & c, Z3_func_interp e):object(c) { init(e); }
func_interp(func_interp const & s):object(s) { init(s.m_interp); }
~func_interp() { Z3_func_interp_dec_ref(ctx(), m_interp); }
operator Z3_func_interp() const { return m_interp; }
func_interp & operator=(func_interp const & s) {
Z3_func_interp_inc_ref(s.ctx(), s.m_interp);
Z3_func_interp_dec_ref(ctx(), m_interp);
m_ctx = s.m_ctx;
m_interp = s.m_interp;
return *this;
}
expr else_value() const { Z3_ast r = Z3_func_interp_get_else(ctx(), m_interp); check_error(); return expr(ctx(), r); }
unsigned num_entries() const { unsigned r = Z3_func_interp_get_num_entries(ctx(), m_interp); check_error(); return r; }
func_entry entry(unsigned i) const { Z3_func_entry e = Z3_func_interp_get_entry(ctx(), m_interp, i); check_error(); return func_entry(ctx(), e); }
};
class model : public object {
Z3_model m_model;
void init(Z3_model m) {
m_model = m;
Z3_model_inc_ref(ctx(), m);
}
public:
model(context & c, Z3_model m):object(c) { init(m); }
model(model const & s):object(s) { init(s.m_model); }
~model() { Z3_model_dec_ref(ctx(), m_model); }
operator Z3_model() const { return m_model; }
model & operator=(model const & s) {
Z3_model_inc_ref(s.ctx(), s.m_model);
Z3_model_dec_ref(ctx(), m_model);
m_ctx = s.m_ctx;
m_model = s.m_model;
return *this;
}
expr eval(expr const & n, bool model_completion=false) const {
check_context(*this, n);
Z3_ast r;
Z3_bool status = Z3_model_eval(ctx(), m_model, n, model_completion, &r);
check_error();
if (status == Z3_FALSE)
throw exception("failed to evaluate expression");
return expr(ctx(), r);
}
unsigned num_consts() const { return Z3_model_get_num_consts(ctx(), m_model); }
unsigned num_funcs() const { return Z3_model_get_num_funcs(ctx(), m_model); }
func_decl get_const_decl(unsigned i) const { Z3_func_decl r = Z3_model_get_const_decl(ctx(), m_model, i); check_error(); return func_decl(ctx(), r); }
func_decl get_func_decl(unsigned i) const { Z3_func_decl r = Z3_model_get_func_decl(ctx(), m_model, i); check_error(); return func_decl(ctx(), r); }
unsigned size() const { return num_consts() + num_funcs(); }
func_decl operator[](unsigned i) const { return i < num_consts() ? get_const_decl(i) : get_func_decl(i - num_consts()); }
expr get_const_interp(func_decl c) const {
check_context(*this, c);
Z3_ast r = Z3_model_get_const_interp(ctx(), m_model, c);
check_error();
return expr(ctx(), r);
}
func_interp get_func_interp(func_decl f) const {
check_context(*this, f);
Z3_func_interp r = Z3_model_get_func_interp(ctx(), m_model, f);
check_error();
return func_interp(ctx(), r);
}
friend std::ostream & operator<<(std::ostream & out, model const & m) { out << Z3_model_to_string(m.ctx(), m); return out; }
};
class stats : public object {
Z3_stats m_stats;
void init(Z3_stats e) {
m_stats = e;
Z3_stats_inc_ref(ctx(), m_stats);
}
public:
stats(context & c):object(c), m_stats(0) {}
stats(context & c, Z3_stats e):object(c) { init(e); }
stats(stats const & s):object(s) { init(s.m_stats); }
~stats() { if (m_stats) Z3_stats_dec_ref(ctx(), m_stats); }
operator Z3_stats() const { return m_stats; }
stats & operator=(stats const & s) {
Z3_stats_inc_ref(s.ctx(), s.m_stats);
if (m_stats) Z3_stats_dec_ref(ctx(), m_stats);
m_ctx = s.m_ctx;
m_stats = s.m_stats;
return *this;
}
unsigned size() const { return Z3_stats_size(ctx(), m_stats); }
std::string key(unsigned i) const { Z3_string s = Z3_stats_get_key(ctx(), m_stats, i); check_error(); return s; }
bool is_uint(unsigned i) const { Z3_bool r = Z3_stats_is_uint(ctx(), m_stats, i); check_error(); return r != 0; }
bool is_double(unsigned i) const { Z3_bool r = Z3_stats_is_double(ctx(), m_stats, i); check_error(); return r != 0; }
unsigned uint_value(unsigned i) const { unsigned r = Z3_stats_get_uint_value(ctx(), m_stats, i); check_error(); return r; }
double double_value(unsigned i) const { double r = Z3_stats_get_double_value(ctx(), m_stats, i); check_error(); return r; }
friend std::ostream & operator<<(std::ostream & out, stats const & s) { out << Z3_stats_to_string(s.ctx(), s); return out; }
};
enum check_result {
unsat, sat, unknown
};
inline std::ostream & operator<<(std::ostream & out, check_result r) {
if (r == unsat) out << "unsat";
else if (r == sat) out << "sat";
else out << "unknown";
return out;
}
inline check_result to_check_result(Z3_lbool l) {
if (l == Z3_L_TRUE) return sat;
else if (l == Z3_L_FALSE) return unsat;
return unknown;
}
class solver : public object {
Z3_solver m_solver;
void init(Z3_solver s) {
m_solver = s;
Z3_solver_inc_ref(ctx(), s);
}
public:
solver(context & c):object(c) { init(Z3_mk_solver(c)); }
solver(context & c, Z3_solver s):object(c) { init(s); }
solver(context & c, char const * logic):object(c) { init(Z3_mk_solver_for_logic(c, c.str_symbol(logic))); }
solver(solver const & s):object(s) { init(s.m_solver); }
~solver() { Z3_solver_dec_ref(ctx(), m_solver); }
operator Z3_solver() const { return m_solver; }
solver & operator=(solver const & s) {
Z3_solver_inc_ref(s.ctx(), s.m_solver);
Z3_solver_dec_ref(ctx(), m_solver);
m_ctx = s.m_ctx;
m_solver = s.m_solver;
return *this;
}
void set(params const & p) { Z3_solver_set_params(ctx(), m_solver, p); check_error(); }
void push() { Z3_solver_push(ctx(), m_solver); check_error(); }
void pop(unsigned n = 1) { Z3_solver_pop(ctx(), m_solver, n); check_error(); }
void reset() { Z3_solver_reset(ctx(), m_solver); check_error(); }
void add(expr const & e) { assert(e.is_bool()); Z3_solver_assert(ctx(), m_solver, e); check_error(); }
check_result check() { Z3_lbool r = Z3_solver_check(ctx(), m_solver); check_error(); return to_check_result(r); }
check_result check(unsigned n, expr * const assumptions) {
array<Z3_ast> _assumptions(n);
for (unsigned i = 0; i < n; i++) {
check_context(*this, assumptions[i]);
_assumptions[i] = assumptions[i];
}
Z3_lbool r = Z3_solver_check_assumptions(ctx(), m_solver, n, _assumptions.ptr());
check_error();
return to_check_result(r);
}
check_result check(expr_vector assumptions) {
unsigned n = assumptions.size();
array<Z3_ast> _assumptions(n);
for (unsigned i = 0; i < n; i++) {
check_context(*this, assumptions[i]);
_assumptions[i] = assumptions[i];
}
Z3_lbool r = Z3_solver_check_assumptions(ctx(), m_solver, n, _assumptions.ptr());
check_error();
return to_check_result(r);
}
model get_model() const { Z3_model m = Z3_solver_get_model(ctx(), m_solver); check_error(); return model(ctx(), m); }
std::string reason_unknown() const { Z3_string r = Z3_solver_get_reason_unknown(ctx(), m_solver); check_error(); return r; }
stats statistics() const { Z3_stats r = Z3_solver_get_statistics(ctx(), m_solver); check_error(); return stats(ctx(), r); }
expr_vector unsat_core() const { Z3_ast_vector r = Z3_solver_get_unsat_core(ctx(), m_solver); check_error(); return expr_vector(ctx(), r); }
expr_vector assertions() const { Z3_ast_vector r = Z3_solver_get_assertions(ctx(), m_solver); check_error(); return expr_vector(ctx(), r); }
expr proof() const { Z3_ast r = Z3_solver_get_proof(ctx(), m_solver); check_error(); return expr(ctx(), r); }
friend std::ostream & operator<<(std::ostream & out, solver const & s) { out << Z3_solver_to_string(s.ctx(), s); return out; }
};
class goal : public object {
Z3_goal m_goal;
void init(Z3_goal s) {
m_goal = s;
Z3_goal_inc_ref(ctx(), s);
}
public:
goal(context & c, bool models=true, bool unsat_cores=false, bool proofs=false):object(c) { init(Z3_mk_goal(c, models, unsat_cores, proofs)); }
goal(context & c, Z3_goal s):object(c) { init(s); }
goal(goal const & s):object(s) { init(s.m_goal); }
~goal() { Z3_goal_dec_ref(ctx(), m_goal); }
operator Z3_goal() const { return m_goal; }
goal & operator=(goal const & s) {
Z3_goal_inc_ref(s.ctx(), s.m_goal);
Z3_goal_dec_ref(ctx(), m_goal);
m_ctx = s.m_ctx;
m_goal = s.m_goal;
return *this;
}
void add(expr const & f) { check_context(*this, f); Z3_goal_assert(ctx(), m_goal, f); check_error(); }
unsigned size() const { return Z3_goal_size(ctx(), m_goal); }
expr operator[](unsigned i) const { Z3_ast r = Z3_goal_formula(ctx(), m_goal, i); check_error(); return expr(ctx(), r); }
Z3_goal_prec precision() const { return Z3_goal_precision(ctx(), m_goal); }
bool inconsistent() const { return Z3_goal_inconsistent(ctx(), m_goal) != 0; }
unsigned depth() const { return Z3_goal_depth(ctx(), m_goal); }
void reset() { Z3_goal_reset(ctx(), m_goal); }
unsigned num_exprs() const { return Z3_goal_num_exprs(ctx(), m_goal); }
bool is_decided_sat() const { return Z3_goal_is_decided_sat(ctx(), m_goal) != 0; }
bool is_decided_unsat() const { return Z3_goal_is_decided_unsat(ctx(), m_goal) != 0; }
friend std::ostream & operator<<(std::ostream & out, goal const & g) { out << Z3_goal_to_string(g.ctx(), g); return out; }
};
class apply_result : public object {
Z3_apply_result m_apply_result;
void init(Z3_apply_result s) {
m_apply_result = s;
Z3_apply_result_inc_ref(ctx(), s);
}
public:
apply_result(context & c, Z3_apply_result s):object(c) { init(s); }
apply_result(apply_result const & s):object(s) { init(s.m_apply_result); }
~apply_result() { Z3_apply_result_dec_ref(ctx(), m_apply_result); }
operator Z3_apply_result() const { return m_apply_result; }
apply_result & operator=(apply_result const & s) {
Z3_apply_result_inc_ref(s.ctx(), s.m_apply_result);
Z3_apply_result_dec_ref(ctx(), m_apply_result);
m_ctx = s.m_ctx;
m_apply_result = s.m_apply_result;
return *this;
}
unsigned size() const { return Z3_apply_result_get_num_subgoals(ctx(), m_apply_result); }
goal operator[](unsigned i) const { Z3_goal r = Z3_apply_result_get_subgoal(ctx(), m_apply_result, i); check_error(); return goal(ctx(), r); }
goal operator[](int i) const { assert(i >= 0); return this->operator[](static_cast<unsigned>(i)); }
model convert_model(model const & m, unsigned i = 0) const {
check_context(*this, m);
Z3_model new_m = Z3_apply_result_convert_model(ctx(), m_apply_result, i, m);
check_error();
return model(ctx(), new_m);
}
friend std::ostream & operator<<(std::ostream & out, apply_result const & r) { out << Z3_apply_result_to_string(r.ctx(), r); return out; }
};
class tactic : public object {
Z3_tactic m_tactic;
void init(Z3_tactic s) {
m_tactic = s;
Z3_tactic_inc_ref(ctx(), s);
}
public:
tactic(context & c, char const * name):object(c) { Z3_tactic r = Z3_mk_tactic(c, name); check_error(); init(r); }
tactic(context & c, Z3_tactic s):object(c) { init(s); }
tactic(tactic const & s):object(s) { init(s.m_tactic); }
~tactic() { Z3_tactic_dec_ref(ctx(), m_tactic); }
operator Z3_tactic() const { return m_tactic; }
tactic & operator=(tactic const & s) {
Z3_tactic_inc_ref(s.ctx(), s.m_tactic);
Z3_tactic_dec_ref(ctx(), m_tactic);
m_ctx = s.m_ctx;
m_tactic = s.m_tactic;
return *this;
}
solver mk_solver() const { Z3_solver r = Z3_mk_solver_from_tactic(ctx(), m_tactic); check_error(); return solver(ctx(), r); }
apply_result apply(goal const & g) const {
check_context(*this, g);
Z3_apply_result r = Z3_tactic_apply(ctx(), m_tactic, g);
check_error();
return apply_result(ctx(), r);
}
apply_result operator()(goal const & g) const {
return apply(g);
}
std::string help() const { char const * r = Z3_tactic_get_help(ctx(), m_tactic); check_error(); return r; }
friend tactic operator&(tactic const & t1, tactic const & t2) {
check_context(t1, t2);
Z3_tactic r = Z3_tactic_and_then(t1.ctx(), t1, t2);
t1.check_error();
return tactic(t1.ctx(), r);
}
friend tactic operator|(tactic const & t1, tactic const & t2) {
check_context(t1, t2);
Z3_tactic r = Z3_tactic_or_else(t1.ctx(), t1, t2);
t1.check_error();
return tactic(t1.ctx(), r);
}
friend tactic repeat(tactic const & t, unsigned max=UINT_MAX) {
Z3_tactic r = Z3_tactic_repeat(t.ctx(), t, max);
t.check_error();
return tactic(t.ctx(), r);
}
friend tactic with(tactic const & t, params const & p) {
Z3_tactic r = Z3_tactic_using_params(t.ctx(), t, p);
t.check_error();
return tactic(t.ctx(), r);
}
friend tactic try_for(tactic const & t, unsigned ms) {
Z3_tactic r = Z3_tactic_try_for(t.ctx(), t, ms);
t.check_error();
return tactic(t.ctx(), r);
}
};
class probe : public object {
Z3_probe m_probe;
void init(Z3_probe s) {
m_probe = s;
Z3_probe_inc_ref(ctx(), s);
}
public:
probe(context & c, char const * name):object(c) { Z3_probe r = Z3_mk_probe(c, name); check_error(); init(r); }
probe(context & c, double val):object(c) { Z3_probe r = Z3_probe_const(c, val); check_error(); init(r); }
probe(context & c, Z3_probe s):object(c) { init(s); }
probe(probe const & s):object(s) { init(s.m_probe); }
~probe() { Z3_probe_dec_ref(ctx(), m_probe); }
operator Z3_probe() const { return m_probe; }
probe & operator=(probe const & s) {
Z3_probe_inc_ref(s.ctx(), s.m_probe);
Z3_probe_dec_ref(ctx(), m_probe);
m_ctx = s.m_ctx;
m_probe = s.m_probe;
return *this;
}
double apply(goal const & g) const { double r = Z3_probe_apply(ctx(), m_probe, g); check_error(); return r; }
double operator()(goal const & g) const { return apply(g); }
friend probe operator<=(probe const & p1, probe const & p2) {
check_context(p1, p2); Z3_probe r = Z3_probe_le(p1.ctx(), p1, p2); p1.check_error(); return probe(p1.ctx(), r);
}
friend probe operator<=(probe const & p1, double p2) { return p1 <= probe(p1.ctx(), p2); }
friend probe operator<=(double p1, probe const & p2) { return probe(p2.ctx(), p1) <= p2; }
friend probe operator>=(probe const & p1, probe const & p2) {
check_context(p1, p2); Z3_probe r = Z3_probe_ge(p1.ctx(), p1, p2); p1.check_error(); return probe(p1.ctx(), r);
}
friend probe operator>=(probe const & p1, double p2) { return p1 >= probe(p1.ctx(), p2); }
friend probe operator>=(double p1, probe const & p2) { return probe(p2.ctx(), p1) >= p2; }
friend probe operator<(probe const & p1, probe const & p2) {
check_context(p1, p2); Z3_probe r = Z3_probe_lt(p1.ctx(), p1, p2); p1.check_error(); return probe(p1.ctx(), r);
}
friend probe operator<(probe const & p1, double p2) { return p1 < probe(p1.ctx(), p2); }
friend probe operator<(double p1, probe const & p2) { return probe(p2.ctx(), p1) < p2; }
friend probe operator>(probe const & p1, probe const & p2) {
check_context(p1, p2); Z3_probe r = Z3_probe_gt(p1.ctx(), p1, p2); p1.check_error(); return probe(p1.ctx(), r);
}
friend probe operator>(probe const & p1, double p2) { return p1 > probe(p1.ctx(), p2); }
friend probe operator>(double p1, probe const & p2) { return probe(p2.ctx(), p1) > p2; }
friend probe operator==(probe const & p1, probe const & p2) {
check_context(p1, p2); Z3_probe r = Z3_probe_eq(p1.ctx(), p1, p2); p1.check_error(); return probe(p1.ctx(), r);
}
friend probe operator==(probe const & p1, double p2) { return p1 == probe(p1.ctx(), p2); }
friend probe operator==(double p1, probe const & p2) { return probe(p2.ctx(), p1) == p2; }
friend probe operator&&(probe const & p1, probe const & p2) {
check_context(p1, p2); Z3_probe r = Z3_probe_and(p1.ctx(), p1, p2); p1.check_error(); return probe(p1.ctx(), r);
}
friend probe operator||(probe const & p1, probe const & p2) {
check_context(p1, p2); Z3_probe r = Z3_probe_or(p1.ctx(), p1, p2); p1.check_error(); return probe(p1.ctx(), r);
}
friend probe operator!(probe const & p) {
Z3_probe r = Z3_probe_not(p.ctx(), p); p.check_error(); return probe(p.ctx(), r);
}
};
inline tactic fail_if(probe const & p) {
Z3_tactic r = Z3_tactic_fail_if(p.ctx(), p);
p.check_error();
return tactic(p.ctx(), r);
}
inline tactic when(probe const & p, tactic const & t) {
check_context(p, t);
Z3_tactic r = Z3_tactic_when(t.ctx(), p, t);
t.check_error();
return tactic(t.ctx(), r);
}
inline tactic cond(probe const & p, tactic const & t1, tactic const & t2) {
check_context(p, t1); check_context(p, t2);
Z3_tactic r = Z3_tactic_cond(t1.ctx(), p, t1, t2);
t1.check_error();
return tactic(t1.ctx(), r);
}
inline symbol context::str_symbol(char const * s) { Z3_symbol r = Z3_mk_string_symbol(m_ctx, s); check_error(); return symbol(*this, r); }
inline symbol context::int_symbol(int n) { Z3_symbol r = Z3_mk_int_symbol(m_ctx, n); check_error(); return symbol(*this, r); }
inline sort context::bool_sort() { Z3_sort s = Z3_mk_bool_sort(m_ctx); check_error(); return sort(*this, s); }
inline sort context::int_sort() { Z3_sort s = Z3_mk_int_sort(m_ctx); check_error(); return sort(*this, s); }
inline sort context::real_sort() { Z3_sort s = Z3_mk_real_sort(m_ctx); check_error(); return sort(*this, s); }
inline sort context::bv_sort(unsigned sz) { Z3_sort s = Z3_mk_bv_sort(m_ctx, sz); check_error(); return sort(*this, s); }
inline sort context::array_sort(sort d, sort r) { Z3_sort s = Z3_mk_array_sort(m_ctx, d, r); check_error(); return sort(*this, s); }
inline func_decl context::function(symbol const & name, unsigned arity, sort const * domain, sort const & range) {
array<Z3_sort> args(arity);
for (unsigned i = 0; i < arity; i++) {
check_context(domain[i], range);
args[i] = domain[i];
}
Z3_func_decl f = Z3_mk_func_decl(m_ctx, name, arity, args.ptr(), range);
check_error();
return func_decl(*this, f);
}
inline func_decl context::function(char const * name, unsigned arity, sort const * domain, sort const & range) {
return function(range.ctx().str_symbol(name), arity, domain, range);
}
inline func_decl context::function(char const * name, sort const & domain, sort const & range) {
check_context(domain, range);
Z3_sort args[1] = { domain };
Z3_func_decl f = Z3_mk_func_decl(m_ctx, str_symbol(name), 1, args, range);
check_error();
return func_decl(*this, f);
}
inline func_decl context::function(char const * name, sort const & d1, sort const & d2, sort const & range) {
check_context(d1, range); check_context(d2, range);
Z3_sort args[2] = { d1, d2 };
Z3_func_decl f = Z3_mk_func_decl(m_ctx, str_symbol(name), 2, args, range);
check_error();
return func_decl(*this, f);
}
inline func_decl context::function(char const * name, sort const & d1, sort const & d2, sort const & d3, sort const & range) {
check_context(d1, range); check_context(d2, range); check_context(d3, range);
Z3_sort args[3] = { d1, d2, d3 };
Z3_func_decl f = Z3_mk_func_decl(m_ctx, str_symbol(name), 3, args, range);
check_error();
return func_decl(*this, f);
}
inline func_decl context::function(char const * name, sort const & d1, sort const & d2, sort const & d3, sort const & d4, sort const & range) {
check_context(d1, range); check_context(d2, range); check_context(d3, range); check_context(d4, range);
Z3_sort args[4] = { d1, d2, d3, d4 };
Z3_func_decl f = Z3_mk_func_decl(m_ctx, str_symbol(name), 4, args, range);
check_error();
return func_decl(*this, f);
}
inline func_decl context::function(char const * name, sort const & d1, sort const & d2, sort const & d3, sort const & d4, sort const & d5, sort const & range) {
check_context(d1, range); check_context(d2, range); check_context(d3, range); check_context(d4, range); check_context(d5, range);
Z3_sort args[5] = { d1, d2, d3, d4, d5 };
Z3_func_decl f = Z3_mk_func_decl(m_ctx, str_symbol(name), 5, args, range);
check_error();
return func_decl(*this, f);
}
inline expr context::constant(symbol const & name, sort const & s) {
Z3_ast r = Z3_mk_const(m_ctx, name, s);
check_error();
return expr(*this, r);
}
inline expr context::constant(char const * name, sort const & s) { return constant(str_symbol(name), s); }
inline expr context::bool_const(char const * name) { return constant(name, bool_sort()); }
inline expr context::int_const(char const * name) { return constant(name, int_sort()); }
inline expr context::real_const(char const * name) { return constant(name, real_sort()); }
inline expr context::bv_const(char const * name, unsigned sz) { return constant(name, bv_sort(sz)); }
inline expr context::bool_val(bool b) { return b ? expr(*this, Z3_mk_true(m_ctx)) : expr(*this, Z3_mk_false(m_ctx)); }
inline expr context::int_val(int n) { Z3_ast r = Z3_mk_int(m_ctx, n, int_sort()); check_error(); return expr(*this, r); }
inline expr context::int_val(unsigned n) { Z3_ast r = Z3_mk_unsigned_int(m_ctx, n, int_sort()); check_error(); return expr(*this, r); }
inline expr context::int_val(__int64 n) { Z3_ast r = Z3_mk_int64(m_ctx, n, int_sort()); check_error(); return expr(*this, r); }
inline expr context::int_val(__uint64 n) { Z3_ast r = Z3_mk_unsigned_int64(m_ctx, n, int_sort()); check_error(); return expr(*this, r); }
inline expr context::int_val(char const * n) { Z3_ast r = Z3_mk_numeral(m_ctx, n, int_sort()); check_error(); return expr(*this, r); }
inline expr context::real_val(int n, int d) { Z3_ast r = Z3_mk_real(m_ctx, n, d); check_error(); return expr(*this, r); }
inline expr context::real_val(int n) { Z3_ast r = Z3_mk_int(m_ctx, n, real_sort()); check_error(); return expr(*this, r); }
inline expr context::real_val(unsigned n) { Z3_ast r = Z3_mk_unsigned_int(m_ctx, n, real_sort()); check_error(); return expr(*this, r); }
inline expr context::real_val(__int64 n) { Z3_ast r = Z3_mk_int64(m_ctx, n, real_sort()); check_error(); return expr(*this, r); }
inline expr context::real_val(__uint64 n) { Z3_ast r = Z3_mk_unsigned_int64(m_ctx, n, real_sort()); check_error(); return expr(*this, r); }
inline expr context::real_val(char const * n) { Z3_ast r = Z3_mk_numeral(m_ctx, n, real_sort()); check_error(); return expr(*this, r); }
inline expr context::bv_val(int n, unsigned sz) { Z3_ast r = Z3_mk_int(m_ctx, n, bv_sort(sz)); check_error(); return expr(*this, r); }
inline expr context::bv_val(unsigned n, unsigned sz) { Z3_ast r = Z3_mk_unsigned_int(m_ctx, n, bv_sort(sz)); check_error(); return expr(*this, r); }
inline expr context::bv_val(__int64 n, unsigned sz) { Z3_ast r = Z3_mk_int64(m_ctx, n, bv_sort(sz)); check_error(); return expr(*this, r); }
inline expr context::bv_val(__uint64 n, unsigned sz) { Z3_ast r = Z3_mk_unsigned_int64(m_ctx, n, bv_sort(sz)); check_error(); return expr(*this, r); }
inline expr context::bv_val(char const * n, unsigned sz) { Z3_ast r = Z3_mk_numeral(m_ctx, n, bv_sort(sz)); check_error(); return expr(*this, r); }
inline expr context::num_val(int n, sort const & s) { Z3_ast r = Z3_mk_int(m_ctx, n, s); check_error(); return expr(*this, r); }
inline expr func_decl::operator()(unsigned n, expr const * args) const {
array<Z3_ast> _args(n);
for (unsigned i = 0; i < n; i++) {
check_context(*this, args[i]);
_args[i] = args[i];
}
Z3_ast r = Z3_mk_app(ctx(), *this, n, _args.ptr());
check_error();
return expr(ctx(), r);
}
inline expr func_decl::operator()(expr const & a) const {
check_context(*this, a);
Z3_ast args[1] = { a };
Z3_ast r = Z3_mk_app(ctx(), *this, 1, args);
ctx().check_error();
return expr(ctx(), r);
}
inline expr func_decl::operator()(int a) const {
Z3_ast args[1] = { ctx().num_val(a, domain(0)) };
Z3_ast r = Z3_mk_app(ctx(), *this, 1, args);
ctx().check_error();
return expr(ctx(), r);
}
inline expr func_decl::operator()(expr const & a1, expr const & a2) const {
check_context(*this, a1); check_context(*this, a2);
Z3_ast args[2] = { a1, a2 };
Z3_ast r = Z3_mk_app(ctx(), *this, 2, args);
ctx().check_error();
return expr(ctx(), r);
}
inline expr func_decl::operator()(expr const & a1, int a2) const {
check_context(*this, a1);
Z3_ast args[2] = { a1, ctx().num_val(a2, domain(1)) };
Z3_ast r = Z3_mk_app(ctx(), *this, 2, args);
ctx().check_error();
return expr(ctx(), r);
}
inline expr func_decl::operator()(int a1, expr const & a2) const {
check_context(*this, a2);
Z3_ast args[2] = { ctx().num_val(a1, domain(0)), a2 };
Z3_ast r = Z3_mk_app(ctx(), *this, 2, args);
ctx().check_error();
return expr(ctx(), r);
}
inline expr func_decl::operator()(expr const & a1, expr const & a2, expr const & a3) const {
check_context(*this, a1); check_context(*this, a2); check_context(*this, a3);
Z3_ast args[3] = { a1, a2, a3 };
Z3_ast r = Z3_mk_app(ctx(), *this, 3, args);
ctx().check_error();
return expr(ctx(), r);
}
inline expr func_decl::operator()(expr const & a1, expr const & a2, expr const & a3, expr const & a4) const {
check_context(*this, a1); check_context(*this, a2); check_context(*this, a3); check_context(*this, a4);
Z3_ast args[4] = { a1, a2, a3, a4 };
Z3_ast r = Z3_mk_app(ctx(), *this, 4, args);
ctx().check_error();
return expr(ctx(), r);
}
inline expr func_decl::operator()(expr const & a1, expr const & a2, expr const & a3, expr const & a4, expr const & a5) const {
check_context(*this, a1); check_context(*this, a2); check_context(*this, a3); check_context(*this, a4); check_context(*this, a5);
Z3_ast args[5] = { a1, a2, a3, a4, a5 };
Z3_ast r = Z3_mk_app(ctx(), *this, 5, args);
ctx().check_error();
return expr(ctx(), r);
}
inline expr to_real(expr const & a) { Z3_ast r = Z3_mk_int2real(a.ctx(), a); a.check_error(); return expr(a.ctx(), r); }
inline func_decl function(symbol const & name, unsigned arity, sort const * domain, sort const & range) {
return range.ctx().function(name, arity, domain, range);
}
inline func_decl function(char const * name, unsigned arity, sort const * domain, sort const & range) {
return range.ctx().function(name, arity, domain, range);
}
inline func_decl function(char const * name, sort const & domain, sort const & range) {
return range.ctx().function(name, domain, range);
}
inline func_decl function(char const * name, sort const & d1, sort const & d2, sort const & range) {
return range.ctx().function(name, d1, d2, range);
}
inline func_decl function(char const * name, sort const & d1, sort const & d2, sort const & d3, sort const & range) {
return range.ctx().function(name, d1, d2, d3, range);
}
inline func_decl function(char const * name, sort const & d1, sort const & d2, sort const & d3, sort const & d4, sort const & range) {
return range.ctx().function(name, d1, d2, d3, d4, range);
}
inline func_decl function(char const * name, sort const & d1, sort const & d2, sort const & d3, sort const & d4, sort const & d5, sort const & range) {
return range.ctx().function(name, d1, d2, d3, d4, d5, range);
}
inline expr select(expr const & a, expr const & i) {
check_context(a, i);
Z3_ast r = Z3_mk_select(a.ctx(), a, i);
a.check_error();
return expr(a.ctx(), r);
}
inline expr select(expr const & a, int i) { return select(a, a.ctx().num_val(i, a.get_sort().array_domain())); }
inline expr store(expr const & a, expr const & i, expr const & v) {
check_context(a, i); check_context(a, v);
Z3_ast r = Z3_mk_store(a.ctx(), a, i, v);
a.check_error();
return expr(a.ctx(), r);
}
inline expr store(expr const & a, int i, expr const & v) { return store(a, a.ctx().num_val(i, a.get_sort().array_domain()), v); }
inline expr store(expr const & a, expr i, int v) { return store(a, i, a.ctx().num_val(v, a.get_sort().array_range())); }
inline expr store(expr const & a, int i, int v) {
return store(a, a.ctx().num_val(i, a.get_sort().array_domain()), a.ctx().num_val(v, a.get_sort().array_range()));
}
inline expr const_array(sort const & d, expr const & v) {
check_context(d, v);
Z3_ast r = Z3_mk_const_array(d.ctx(), d, v);
d.check_error();
return expr(d.ctx(), r);
}
};
template class z3::ast_vector_tpl<z3::ast>;
template class z3::ast_vector_tpl<z3::expr>;
template class z3::ast_vector_tpl<z3::sort>;
template class z3::ast_vector_tpl<z3::func_decl>;
#endif