/* Copyright (c) 2014 Microsoft Corporation. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Author: Leonardo de Moura */ #include "util/rc.h" #include "kernel/expr.h" #include "kernel/justification.h" #include "kernel/metavar.h" #include "kernel/constraint.h" namespace lean { struct constraint_cell { void dealloc(); MK_LEAN_RC() constraint_kind m_kind; justification m_jst; constraint_cell(constraint_kind k, justification const & j): m_rc(1), m_kind(k), m_jst(j) {} }; struct eq_constraint_cell : public constraint_cell { expr m_lhs; expr m_rhs; eq_constraint_cell(expr const & lhs, expr const & rhs, justification const & j): constraint_cell(constraint_kind::Eq, j), m_lhs(lhs), m_rhs(rhs) {} }; struct level_constraint_cell : public constraint_cell { level m_lhs; level m_rhs; level_constraint_cell(level const & lhs, level const & rhs, justification const & j): constraint_cell(constraint_kind::LevelEq, j), m_lhs(lhs), m_rhs(rhs) {} }; struct choice_constraint_cell : public constraint_cell { expr m_expr; choice_fn m_fn; delay_factor m_delay_factor; bool m_owner; choice_constraint_cell(expr const & e, choice_fn const & fn, delay_factor const & f, bool owner, justification const & j): constraint_cell(constraint_kind::Choice, j), m_expr(e), m_fn(fn), m_delay_factor(f), m_owner(owner) {} }; void constraint_cell::dealloc() { switch (m_kind) { case constraint_kind::Eq: delete static_cast(this); break; case constraint_kind::LevelEq: delete static_cast(this); break; case constraint_kind::Choice: delete static_cast(this); break; } } constraint::constraint(constraint_cell * ptr):m_ptr(ptr) { lean_assert(m_ptr->get_rc() == 1); } constraint::constraint(constraint const & s):m_ptr(s.m_ptr) { if (m_ptr) m_ptr->inc_ref(); } constraint::constraint(constraint && s):m_ptr(s.m_ptr) { s.m_ptr = nullptr; } constraint::~constraint() { if (m_ptr) m_ptr->dec_ref(); } constraint & constraint::operator=(constraint const & c) { LEAN_COPY_REF(c); } constraint & constraint::operator=(constraint && c) { LEAN_MOVE_REF(c); } constraint_kind constraint::kind() const { lean_assert(m_ptr); return m_ptr->m_kind; } justification const & constraint::get_justification() const { lean_assert(m_ptr); return m_ptr->m_jst; } constraint mk_eq_cnstr(expr const & lhs, expr const & rhs, justification const & j) { return constraint(new eq_constraint_cell(lhs, rhs, j)); } constraint mk_level_eq_cnstr(level const & lhs, level const & rhs, justification const & j) { return constraint(new level_constraint_cell(lhs, rhs, j)); } constraint mk_choice_cnstr(expr const & m, choice_fn const & fn, delay_factor const & f, bool owner, justification const & j) { lean_assert(is_meta(m)); return constraint(new choice_constraint_cell(m, fn, f, owner, j)); } expr const & cnstr_lhs_expr(constraint const & c) { lean_assert(is_eq_cnstr(c)); return static_cast(c.raw())->m_lhs; } expr const & cnstr_rhs_expr(constraint const & c) { lean_assert(is_eq_cnstr(c)); return static_cast(c.raw())->m_rhs; } level const & cnstr_lhs_level(constraint const & c) { lean_assert(is_level_eq_cnstr(c)); return static_cast(c.raw())->m_lhs; } level const & cnstr_rhs_level(constraint const & c) { lean_assert(is_level_eq_cnstr(c)); return static_cast(c.raw())->m_rhs; } expr const & cnstr_expr(constraint const & c) { lean_assert(is_choice_cnstr(c)); return static_cast(c.raw())->m_expr; } choice_fn const & cnstr_choice_fn(constraint const & c) { lean_assert(is_choice_cnstr(c)); return static_cast(c.raw())->m_fn; } bool cnstr_on_demand(constraint const & c) { lean_assert(is_choice_cnstr(c)); return static_cast(c.raw())->m_delay_factor.on_demand(); } delay_factor const & cnstr_delay_factor_core(constraint const & c) { lean_assert(is_choice_cnstr(c)); return static_cast(c.raw())->m_delay_factor; } unsigned cnstr_delay_factor(constraint const & c) { return cnstr_delay_factor_core(c).explict_value(); } bool cnstr_is_owner(constraint const & c) { lean_assert(is_choice_cnstr(c)); return static_cast(c.raw())->m_owner; } constraint update_justification(constraint const & c, justification const & j) { switch (c.kind()) { case constraint_kind::Eq: return mk_eq_cnstr(cnstr_lhs_expr(c), cnstr_rhs_expr(c), j); case constraint_kind::LevelEq: return mk_level_eq_cnstr(cnstr_lhs_level(c), cnstr_rhs_level(c), j); case constraint_kind::Choice: return mk_choice_cnstr(cnstr_expr(c), cnstr_choice_fn(c), static_cast(c.raw())->m_delay_factor, cnstr_is_owner(c), j); } lean_unreachable(); // LCOV_EXCL_LINE } void to_buffer(constraint_seq const & cs, justification const & j, buffer & r) { return cs.for_each([&](constraint const & c) { r.push_back(update_justification(c, mk_composite1(c.get_justification(), j))); }); } std::ostream & operator<<(std::ostream & out, constraint const & c) { switch (c.kind()) { case constraint_kind::Eq: out << cnstr_lhs_expr(c) << " ≈ " << cnstr_rhs_expr(c); break; case constraint_kind::LevelEq: out << cnstr_lhs_level(c) << " = " << cnstr_rhs_level(c); break; case constraint_kind::Choice: out << "choice "; if (cnstr_on_demand(c)) out << "[on-demand]"; else if (cnstr_delay_factor(c) != 0) out << "[delayed:" << cnstr_delay_factor(c) << "] "; out << cnstr_expr(c); break; } return out; } } void print(lean::constraint const & c) { std::cout << c << "\n"; }