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Refactor finite_sets_decl_plugin to use polymorphic signatures and Array sorts

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Co-authored-by: NikolajBjorner <3085284+NikolajBjorner@users.noreply.github.com>
This commit is contained in:
copilot-swe-agent[bot] 2025-10-05 16:14:32 +00:00
parent 980ea35b0e
commit aa9cb71f6b
3 changed files with 186 additions and 299 deletions
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400
src/ast/finite_sets_decl_plugin.cpp
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@ -19,20 +19,132 @@ Revision History:
#include<sstream>
#include "ast/finite_sets_decl_plugin.h"
#include "ast/arith_decl_plugin.h"
#include "ast/array_decl_plugin.h"
#include "util/warning.h"
finite_sets_decl_plugin::finite_sets_decl_plugin():
m_empty_sym("set.empty"),
m_singleton_sym("set.singleton"),
m_union_sym("set.union"),
m_intersect_sym("set.intersect"),
m_difference_sym("set.difference"),
m_in_sym("set.in"),
m_size_sym("set.size"),
m_subset_sym("set.subset"),
m_map_sym("set.map"),
m_filter_sym("set.filter"),
m_range_sym("set.range") {
m_init(false) {
}
finite_sets_decl_plugin::~finite_sets_decl_plugin() {
for (psig* s : m_sigs)
dealloc(s);
}
bool finite_sets_decl_plugin::is_sort_param(sort* s, unsigned& idx) {
return
s->get_name().is_numerical() &&
(idx = s->get_name().get_num(), true);
}
bool finite_sets_decl_plugin::match(ptr_vector<sort>& binding, sort* s, sort* sP) {
if (s == sP) return true;
unsigned idx;
if (is_sort_param(sP, idx)) {
if (binding.size() <= idx) binding.resize(idx+1);
if (binding[idx] && (binding[idx] != s)) return false;
binding[idx] = s;
return true;
}
if (s->get_family_id() == sP->get_family_id() &&
s->get_decl_kind() == sP->get_decl_kind() &&
s->get_num_parameters() == sP->get_num_parameters()) {
for (unsigned i = 0, sz = s->get_num_parameters(); i < sz; ++i) {
parameter const& p = s->get_parameter(i);
if (p.is_ast() && is_sort(p.get_ast())) {
parameter const& p2 = sP->get_parameter(i);
if (!match(binding, to_sort(p.get_ast()), to_sort(p2.get_ast()))) return false;
}
}
return true;
}
else {
return false;
}
}
void finite_sets_decl_plugin::match(psig& sig, unsigned dsz, sort *const* dom, sort* range, sort_ref& range_out) {
m_binding.reset();
ast_manager& m = *m_manager;
if (dsz != sig.m_dom.size()) {
std::ostringstream strm;
strm << "Incorrect number of arguments to '" << sig.m_name << "' ";
strm << "expected " << sig.m_dom.size() << " given " << dsz;
m.raise_exception(strm.str());
}
bool is_match = true;
for (unsigned i = 0; is_match && i < dsz; ++i) {
SASSERT(dom[i]);
is_match = match(m_binding, dom[i], sig.m_dom.get(i));
}
if (range && is_match) {
is_match = match(m_binding, range, sig.m_range);
}
if (!is_match) {
std::ostringstream strm;
strm << "Sort mismatch for function '" << sig.m_name << "'";
m.raise_exception(strm.str());
}
// Compute range_out by substituting binding into sig.m_range
range_out = sig.m_range;
unsigned idx;
if (is_sort_param(sig.m_range, idx) && idx < m_binding.size() && m_binding[idx]) {
range_out = m_binding[idx];
}
else if (sig.m_range->get_family_id() == m_family_id &&
sig.m_range->get_decl_kind() == FINITE_SET_SORT) {
parameter const& p = sig.m_range->get_parameter(0);
if (p.is_ast() && is_sort(p.get_ast())) {
sort* elem_sort = to_sort(p.get_ast());
if (is_sort_param(elem_sort, idx) && idx < m_binding.size() && m_binding[idx]) {
parameter new_param(m_binding[idx]);
range_out = m.mk_sort(m_family_id, FINITE_SET_SORT, 1, &new_param);
}
}
}
}
void finite_sets_decl_plugin::init() {
if (m_init) return;
ast_manager& m = *m_manager;
array_util autil(m);
m_init = true;
sort* A = m.mk_uninterpreted_sort(symbol(0u));
sort* B = m.mk_uninterpreted_sort(symbol(1u));
parameter paramA(A);
parameter paramB(B);
sort* setA = m.mk_sort(m_family_id, FINITE_SET_SORT, 1, &paramA);
sort* setB = m.mk_sort(m_family_id, FINITE_SET_SORT, 1, &paramB);
sort* boolT = m.mk_bool_sort();
sort* intT = arith_util(m).mk_int();
parameter paramInt(intT);
sort* setInt = m.mk_sort(m_family_id, FINITE_SET_SORT, 1, &paramInt);
sort* arrAB = autil.mk_array_sort(A, B);
sort* arrABool = autil.mk_array_sort(A, boolT);
sort* setAsetA[2] = { setA, setA };
sort* AsetA[2] = { A, setA };
sort* arrABsetA[2] = { arrAB, setA };
sort* arrABoolsetA[2] = { arrABool, setA };
sort* intintT[2] = { intT, intT };
m_sigs.resize(LAST_FINITE_SET_OP);
m_sigs[OP_FINITE_SET_EMPTY] = alloc(psig, m, "set.empty", 1, 0, nullptr, setA);
m_sigs[OP_FINITE_SET_SINGLETON] = alloc(psig, m, "set.singleton", 1, 1, &A, setA);
m_sigs[OP_FINITE_SET_UNION] = alloc(psig, m, "set.union", 1, 2, setAsetA, setA);
m_sigs[OP_FINITE_SET_INTERSECT] = alloc(psig, m, "set.intersect", 1, 2, setAsetA, setA);
m_sigs[OP_FINITE_SET_DIFFERENCE] = alloc(psig, m, "set.difference", 1, 2, setAsetA, setA);
m_sigs[OP_FINITE_SET_IN] = alloc(psig, m, "set.in", 1, 2, AsetA, boolT);
m_sigs[OP_FINITE_SET_SIZE] = alloc(psig, m, "set.size", 1, 1, &setA, intT);
m_sigs[OP_FINITE_SET_SUBSET] = alloc(psig, m, "set.subset", 1, 2, setAsetA, boolT);
m_sigs[OP_FINITE_SET_MAP] = alloc(psig, m, "set.map", 2, 2, arrABsetA, setB);
m_sigs[OP_FINITE_SET_FILTER] = alloc(psig, m, "set.filter", 1, 2, arrABoolsetA, setA);
m_sigs[OP_FINITE_SET_RANGE] = alloc(psig, m, "set.range", 0, 2, intintT, setInt);
}
sort * finite_sets_decl_plugin::mk_sort(decl_kind k, unsigned num_parameters, parameter const * parameters) {
@ -66,242 +178,27 @@ sort * finite_sets_decl_plugin::get_element_sort(sort* finite_set_sort) const {
return to_sort(params[0].get_ast());
}
bool finite_sets_decl_plugin::check_finite_set_arguments(unsigned arity, sort * const * domain) {
if (arity == 0) {
return true;
}
sort* first_sort = domain[0];
if (first_sort->get_family_id() != m_family_id ||
first_sort->get_decl_kind() != FINITE_SET_SORT) {
m_manager->raise_exception("argument is not of FiniteSet sort");
return false;
}
for (unsigned i = 1; i < arity; ++i) {
if (domain[i] != first_sort) {
std::ostringstream buffer;
buffer << "arguments " << 1 << " and " << (i+1) << " have different sorts";
m_manager->raise_exception(buffer.str());
return false;
}
}
return true;
}
func_decl * finite_sets_decl_plugin::mk_empty(sort* element_sort) {
parameter param(element_sort);
sort * finite_set_sort = m_manager->mk_sort(m_family_id, FINITE_SET_SORT, 1, &param);
sort * const * no_domain = nullptr;
return m_manager->mk_func_decl(m_empty_sym, 0u, no_domain, finite_set_sort,
return m_manager->mk_func_decl(m_sigs[OP_FINITE_SET_EMPTY]->m_name, 0u, no_domain, finite_set_sort,
func_decl_info(m_family_id, OP_FINITE_SET_EMPTY, 1, &param));
}
func_decl * finite_sets_decl_plugin::mk_singleton(unsigned arity, sort * const * domain) {
if (arity != 1) {
m_manager->raise_exception("set.singleton takes exactly one argument");
return nullptr;
}
// The element sort is the domain
sort* element_sort = domain[0];
// Create the result sort: FiniteSet of the element type
parameter param(element_sort);
sort* finite_set_sort = m_manager->mk_sort(m_family_id, FINITE_SET_SORT, 1, &param);
return m_manager->mk_func_decl(m_singleton_sym, arity, domain, finite_set_sort,
func_decl_info(m_family_id, OP_FINITE_SET_SINGLETON));
}
func_decl * finite_sets_decl_plugin::mk_union(unsigned arity, sort * const * domain) {
if (arity != 2) {
m_manager->raise_exception("set.union takes exactly two arguments");
return nullptr;
}
if (!check_finite_set_arguments(arity, domain)) {
return nullptr;
}
return m_manager->mk_func_decl(m_union_sym, arity, domain, domain[0],
func_decl_info(m_family_id, OP_FINITE_SET_UNION));
}
func_decl * finite_sets_decl_plugin::mk_intersect(unsigned arity, sort * const * domain) {
if (arity != 2) {
m_manager->raise_exception("set.intersect takes exactly two arguments");
return nullptr;
}
if (!check_finite_set_arguments(arity, domain)) {
return nullptr;
}
return m_manager->mk_func_decl(m_intersect_sym, arity, domain, domain[0],
func_decl_info(m_family_id, OP_FINITE_SET_INTERSECT));
}
func_decl * finite_sets_decl_plugin::mk_difference(unsigned arity, sort * const * domain) {
if (arity != 2) {
m_manager->raise_exception("set.difference takes exactly two arguments");
return nullptr;
}
if (!check_finite_set_arguments(arity, domain)) {
return nullptr;
}
return m_manager->mk_func_decl(m_difference_sym, arity, domain, domain[0],
func_decl_info(m_family_id, OP_FINITE_SET_DIFFERENCE));
}
func_decl * finite_sets_decl_plugin::mk_in(unsigned arity, sort * const * domain) {
if (arity != 2) {
m_manager->raise_exception("set.in takes exactly two arguments");
return nullptr;
}
if (domain[1]->get_family_id() != m_family_id ||
domain[1]->get_decl_kind() != FINITE_SET_SORT) {
m_manager->raise_exception("second argument of set.in must be a FiniteSet");
return nullptr;
}
sort* element_sort = get_element_sort(domain[1]);
if (!element_sort) {
m_manager->raise_exception("invalid FiniteSet sort");
return nullptr;
}
if (domain[0] != element_sort) {
m_manager->raise_exception("element type does not match set element type");
return nullptr;
}
sort* bool_sort = m_manager->mk_bool_sort();
return m_manager->mk_func_decl(m_in_sym, arity, domain, bool_sort,
func_decl_info(m_family_id, OP_FINITE_SET_IN));
}
func_decl * finite_sets_decl_plugin::mk_size(unsigned arity, sort * const * domain) {
if (arity != 1) {
m_manager->raise_exception("set.size takes exactly one argument");
return nullptr;
}
if (!check_finite_set_arguments(arity, domain)) {
return nullptr;
}
arith_util arith(*m_manager);
sort * int_sort = arith.mk_int();
return m_manager->mk_func_decl(m_size_sym, arity, domain, int_sort,
func_decl_info(m_family_id, OP_FINITE_SET_SIZE));
}
func_decl * finite_sets_decl_plugin::mk_subset(unsigned arity, sort * const * domain) {
if (arity != 2) {
m_manager->raise_exception("set.subset takes exactly two arguments");
return nullptr;
}
if (!check_finite_set_arguments(arity, domain)) {
return nullptr;
}
sort* bool_sort = m_manager->mk_bool_sort();
return m_manager->mk_func_decl(m_subset_sym, arity, domain, bool_sort,
func_decl_info(m_family_id, OP_FINITE_SET_SUBSET));
}
func_decl * finite_sets_decl_plugin::mk_map(func_decl* f, unsigned arity, sort* const* domain) {
if (arity != 1) {
m_manager->raise_exception("set.map takes exactly one set argument");
return nullptr;
}
if (!check_finite_set_arguments(arity, domain)) {
return nullptr;
}
// Get the element sort of the input set
sort* input_element_sort = get_element_sort(domain[0]);
if (!input_element_sort) {
m_manager->raise_exception("invalid FiniteSet sort");
return nullptr;
}
// Check that the function has correct signature
if (f->get_arity() != 1) {
m_manager->raise_exception("set.map function must take exactly one argument");
return nullptr;
}
if (f->get_domain(0) != input_element_sort) {
m_manager->raise_exception("set.map function domain must match set element type");
return nullptr;
}
// Create output set sort with the function's range as element type
sort* output_element_sort = f->get_range();
parameter param(output_element_sort);
sort* output_set_sort = m_manager->mk_sort(m_family_id, FINITE_SET_SORT, 1, &param);
parameter func_param(f);
return m_manager->mk_func_decl(m_map_sym, arity, domain, output_set_sort,
func_decl_info(m_family_id, OP_FINITE_SET_MAP, 1, &func_param));
}
func_decl * finite_sets_decl_plugin::mk_filter(func_decl* f, unsigned arity, sort* const* domain) {
if (arity != 1) {
m_manager->raise_exception("set.filter takes exactly one set argument");
return nullptr;
}
if (!check_finite_set_arguments(arity, domain)) {
return nullptr;
}
// Get the element sort of the set
sort* element_sort = get_element_sort(domain[0]);
if (!element_sort) {
m_manager->raise_exception("invalid FiniteSet sort");
return nullptr;
}
// Check that the function has correct signature (S -> Bool)
if (f->get_arity() != 1) {
m_manager->raise_exception("set.filter function must take exactly one argument");
return nullptr;
}
if (f->get_domain(0) != element_sort) {
m_manager->raise_exception("set.filter function domain must match set element type");
return nullptr;
}
if (!m_manager->is_bool(f->get_range())) {
m_manager->raise_exception("set.filter function must return Bool");
return nullptr;
}
parameter func_param(f);
return m_manager->mk_func_decl(m_filter_sym, arity, domain, domain[0],
func_decl_info(m_family_id, OP_FINITE_SET_FILTER, 1, &func_param));
}
func_decl * finite_sets_decl_plugin::mk_range(unsigned arity, sort * const * domain) {
if (arity != 2) {
m_manager->raise_exception("set.range takes exactly two arguments");
return nullptr;
}
arith_util arith(*m_manager);
sort * int_sort = arith.mk_int();
if (domain[0] != int_sort || domain[1] != int_sort) {
m_manager->raise_exception("set.range arguments must be Int");
return nullptr;
}
parameter param(int_sort);
sort* output_set_sort = m_manager->mk_sort(m_family_id, FINITE_SET_SORT, 1, &param);
return m_manager->mk_func_decl(m_range_sym, arity, domain, output_set_sort,
func_decl_info(m_family_id, OP_FINITE_SET_RANGE));
func_decl * finite_sets_decl_plugin::mk_finite_set_op(decl_kind k, unsigned arity, sort * const * domain, sort* range) {
ast_manager& m = *m_manager;
sort_ref rng(m);
match(*m_sigs[k], arity, domain, range, rng);
return m.mk_func_decl(m_sigs[k]->m_name, arity, domain, rng, func_decl_info(m_family_id, k));
}
func_decl * finite_sets_decl_plugin::mk_func_decl(decl_kind k, unsigned num_parameters,
parameter const * parameters,
unsigned arity, sort * const * domain,
sort * range) {
init();
switch (k) {
case OP_FINITE_SET_EMPTY:
if (num_parameters != 1 || !parameters[0].is_ast() || !is_sort(parameters[0].get_ast())) {
@ -310,50 +207,27 @@ func_decl * finite_sets_decl_plugin::mk_func_decl(decl_kind k, unsigned num_para
}
return mk_empty(to_sort(parameters[0].get_ast()));
case OP_FINITE_SET_SINGLETON:
return mk_singleton(arity, domain);
case OP_FINITE_SET_UNION:
return mk_union(arity, domain);
case OP_FINITE_SET_INTERSECT:
return mk_intersect(arity, domain);
case OP_FINITE_SET_DIFFERENCE:
return mk_difference(arity, domain);
case OP_FINITE_SET_IN:
return mk_in(arity, domain);
case OP_FINITE_SET_SIZE:
return mk_size(arity, domain);
case OP_FINITE_SET_SUBSET:
return mk_subset(arity, domain);
case OP_FINITE_SET_MAP:
if (num_parameters != 1 || !parameters[0].is_ast() || !is_func_decl(parameters[0].get_ast())) {
m_manager->raise_exception("set.map requires one function parameter");
return nullptr;
}
return mk_map(to_func_decl(parameters[0].get_ast()), arity, domain);
case OP_FINITE_SET_FILTER:
if (num_parameters != 1 || !parameters[0].is_ast() || !is_func_decl(parameters[0].get_ast())) {
m_manager->raise_exception("set.filter requires one function parameter");
return nullptr;
}
return mk_filter(to_func_decl(parameters[0].get_ast()), arity, domain);
case OP_FINITE_SET_RANGE:
return mk_range(arity, domain);
return mk_finite_set_op(k, arity, domain, range);
default:
return nullptr;
}
}
void finite_sets_decl_plugin::get_op_names(svector<builtin_name>& op_names, symbol const & logic) {
op_names.push_back(builtin_name("set.empty", OP_FINITE_SET_EMPTY));
op_names.push_back(builtin_name("set.singleton", OP_FINITE_SET_SINGLETON));
op_names.push_back(builtin_name("set.union", OP_FINITE_SET_UNION));
op_names.push_back(builtin_name("set.intersect", OP_FINITE_SET_INTERSECT));
op_names.push_back(builtin_name("set.difference", OP_FINITE_SET_DIFFERENCE));
op_names.push_back(builtin_name("set.in", OP_FINITE_SET_IN));
op_names.push_back(builtin_name("set.size", OP_FINITE_SET_SIZE));
op_names.push_back(builtin_name("set.subset", OP_FINITE_SET_SUBSET));
op_names.push_back(builtin_name("set.map", OP_FINITE_SET_MAP));
op_names.push_back(builtin_name("set.filter", OP_FINITE_SET_FILTER));
op_names.push_back(builtin_name("set.range", OP_FINITE_SET_RANGE));
init();
for (unsigned i = 0; i < m_sigs.size(); ++i) {
if (m_sigs[i])
op_names.push_back(builtin_name(m_sigs[i]->m_name.str(), i));
}
}
void finite_sets_decl_plugin::get_sort_names(svector<builtin_name>& sort_names, symbol const & logic) {