/* Copyright (c) 2013 Microsoft Corporation. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Author: Leonardo de Moura */ #include "test.h" #include "metavar_env.h" #include "elaborator.h" #include "printer.h" #include "occurs.h" #include "abstract.h" #include "toplevel.h" #include "basic_thms.h" #include "kernel_exception.h" using namespace lean; static name g_placeholder_name(name(name(name(0u), "library"), "placeholder")); /** \brief Return a new placeholder expression. To be able to track location, a new constant for each placeholder. */ expr mk_placholder() { return mk_constant(g_placeholder_name); } /** \brief Return true iff the given expression is a placeholder. */ bool is_placeholder(expr const & e) { return is_constant(e) && const_name(e) == g_placeholder_name; } /** \brief Return true iff the given expression contains placeholders. */ bool has_placeholder(expr const & e) { return occurs(mk_placholder(), e); } std::ostream & operator<<(std::ostream & out, metavar_env const & uf) { uf.display(out); return out; } /** \brief Auxiliary function for #replace_placeholders_with_metavars */ static expr replace(expr const & e, context const & ctx, metavar_env & menv) { switch (e.kind()) { case expr_kind::Constant: if (is_placeholder(e)) { return menv.mk_metavar(ctx); } else { return e; } case expr_kind::Var: case expr_kind::Type: case expr_kind::Value: return e; case expr_kind::App: return update_app(e, [&](expr const & c) { return replace(c, ctx, menv); }); case expr_kind::Eq: return update_eq(e, [&](expr const & l, expr const & r) { return mk_pair(replace(l, ctx, menv), replace(r, ctx, menv)); }); case expr_kind::Lambda: case expr_kind::Pi: return update_abst(e, [&](expr const & d, expr const & b) { expr new_d = replace(d, ctx, menv); expr new_b = replace(b, extend(ctx, abst_name(e), new_d), menv); return mk_pair(new_d, new_b); }); case expr_kind::Let: return update_let(e, [&](expr const & v, expr const & b) { expr new_v = replace(v, ctx, menv); expr new_b = replace(b, extend(ctx, abst_name(e), expr(), new_v), menv); return mk_pair(new_v, new_b); }); } lean_unreachable(); return e; } /** \brief Replace placeholders with fresh meta-variables. */ expr replace_placeholders_with_metavars(expr const & e, metavar_env & menv) { return replace(e, context(), menv); } expr elaborate(elaborator & elb, expr const & e) { expr new_e = replace_placeholders_with_metavars(e, elb.menv()); return elb(new_e); } static void tst1() { expr m1 = mk_metavar(0); expr m2 = mk_metavar(1); expr a = Const("a"); expr f = Const("f"); lean_assert(is_metavar(m1)); lean_assert(!is_metavar(a)); lean_assert(metavar_idx(m1) == 0); lean_assert(metavar_idx(m2) == 1); lean_assert(m1 != m2); lean_assert(a != m1); std::cout << m1 << " " << m2 << "\n"; lean_assert(has_metavar(m1)); lean_assert(has_metavar(f(f(f(m1))))); lean_assert(!has_metavar(f(f(a)))); } static void tst2() { environment env; metavar_env u(env); expr m1 = u.mk_metavar(); expr m2 = u.mk_metavar(); expr m3 = u.mk_metavar(); lean_assert(!u.is_assigned(m1)); lean_assert(!u.is_assigned(m2)); lean_assert(!u.is_assigned(m3)); expr f = Const("f"); expr t1 = f(m1, m2); expr t2 = f(m1, m1); lean_assert(t1 != t2); lean_assert(!u.is_modulo_eq(t1, t2)); // m1 <- m2 u.assign(m1, m2); std::cout << u << "\n"; lean_assert(u.root(m2) == m2); lean_assert(u.root(m1) == m2); lean_assert(u.is_modulo_eq(t1, t2)); expr a = Const("a"); expr b = Const("b"); expr g = Const("g"); expr t3 = f(a, m1); expr t4 = f(m2, a); expr t5 = f(a, a); lean_assert(t3 != t4); lean_assert(t4 != t5); lean_assert(!u.is_modulo_eq(t3, t4)); lean_assert(!u.is_modulo_eq(t4, t5)); u.assign(m2, a); lean_assert(u.is_modulo_eq(t3, t4)); lean_assert(u.is_modulo_eq(t4, t5)); lean_assert(u.is_modulo_eq(g(t3, m1), g(t4, a))); lean_assert(!u.is_modulo_eq(g(t3, m3), g(t4, b))); u.assign(m3, b); lean_assert(u.is_modulo_eq(g(t3, m3), g(t4, b))); std::cout << u << "\n"; expr m4 = u.mk_metavar(); std::cout << u << "\n"; u.assign(m4, m1); std::cout << u << "\n"; expr m5 = u.mk_metavar(); expr m6 = u.mk_metavar(); u.assign(m5, m6); metavar_env u2(u); u.assign(m5, m3); std::cout << u << "\n"; u2.assign(m5, m2); std::cout << u2 << "\n"; } static void tst3() { environment env; metavar_env uenv(env); expr m1 = uenv.mk_metavar(); expr f = Const("f"); expr a = Const("a"); expr b = Const("b"); expr g = Const("g"); expr m2 = uenv.mk_metavar(); uenv.assign(m2, f(m1, a)); uenv.assign(m1, b); std::cout << uenv.instantiate_metavars(g(m2,b)) << "\n"; lean_assert(uenv.instantiate_metavars(g(m2,b)) == g(f(b,a), b)); lean_assert(uenv.instantiate_metavars(g(m2,f(a,m1))) == g(f(b,a),f(a,b))); expr m3 = uenv.mk_metavar(); expr m4 = uenv.mk_metavar(); uenv.assign(m3, f(m4)); try { uenv.assign(m4, f(m3)); lean_unreachable(); } catch (exception) { } } static void tst4() { environment env; metavar_env uenv(env); expr m1 = uenv.mk_metavar(); expr m2 = uenv.mk_metavar(); uenv.assign(m1, m2); expr f = Const("f"); expr a = Const("a"); expr t = uenv.instantiate_metavars(f(m1,f(a, m1))); std::cout << t << "\n"; lean_assert(t == f(m2, f(a, m2))); } static void tst5() { environment env; env.add_var("A", Type()); env.add_var("B", Type()); expr A = Const("A"); expr B = Const("B"); env.add_definition("F", Type(), A >> B); env.add_definition("G", Type(), B >> B); metavar_env uenv(env); expr m1 = uenv.mk_metavar(); expr m2 = uenv.mk_metavar(); expr m3 = uenv.mk_metavar(); expr m4 = uenv.mk_metavar(); expr F = Const("F"); expr G = Const("G"); expr f = Const("f"); expr g = Const("g"); expr a = Const("a"); expr b = Const("b"); expr x = Const("x"); expr Id = Fun({x, A}, x); expr t1 = f(m1, g(a, F)); expr t2 = f(g(a, b), Id(g(m2, m3 >> m4))); metavar_env uenv2(uenv); uenv2.unify(t1, t2); std::cout << uenv2 << "\n"; lean_assert(uenv2.root(m1) == g(a, b)); lean_assert(uenv2.root(m2) == a); lean_assert(uenv2.root(m3) == A); lean_assert(uenv2.root(m4) == B); lean_assert(uenv2.instantiate_metavars(t1) == f(g(a, b), g(a, F))); lean_assert(uenv2.instantiate_metavars(t2) == f(g(a, b), Id(g(a, A >> B)))); metavar_env uenv3(uenv); expr t3 = f(m1, m1 >> m1); expr t4 = f(m2 >> m2, m3); uenv3.unify(t3, t4); std::cout << uenv3 << "\n"; uenv3.unify(m1, G); std::cout << uenv3 << "\n"; std::cout << uenv3.instantiate_metavars(t3) << "\n"; } static void tst6() { environment env; env.add_var("A", Type()); expr A = Const("A"); expr f = Const("f"); expr g = Const("g"); expr a = Const("a"); expr b = Const("b"); context ctx1; ctx1 = extend(extend(ctx1, "x", A >> A), "y", A); metavar_env uenv(env); expr m1 = uenv.mk_metavar(); expr m2 = uenv.mk_metavar(ctx1); context ctx2; ctx2 = extend(ctx2, "x", m1); expr m3 = uenv.mk_metavar(ctx2); metavar_env uenv2(uenv); expr t1 = f(m2, m3); expr t2 = f(g(m3), Var(0)); std::cout << "----------------\n"; std::cout << uenv << "\n"; uenv.unify(t1, t2); std::cout << uenv << "\n"; std::cout << uenv.instantiate_metavars(t1) << "\n"; std::cout << uenv.instantiate_metavars(t2) << "\n"; lean_assert(uenv.instantiate_metavars(t1) == uenv.instantiate_metavars(t2)); lean_assert(uenv.instantiate_metavars(t2) == f(g(Var(0)), Var(0))); lean_assert(uenv.instantiate_metavars(m1) == A >> A); expr t3 = f(m2); expr t4 = f(m3); uenv2.unify(t3, t4); std::cout << "----------------\n"; std::cout << uenv2 << "\n"; lean_assert(uenv2.instantiate_metavars(m1) == A >> A); lean_assert(length(uenv2.get_context(m2)) == length(uenv2.get_context(m3))); } static void tst7() { environment env; env.add_var("A", Type()); env.add_var("B", Type()); expr A = Const("A"); expr B = Const("B"); env.add_definition("F", Type(), A >> B); env.add_definition("G", Type(), B >> B); name_set S; S.insert("G"); metavar_env uenv(env, &S); expr m1 = uenv.mk_metavar(); expr m2 = uenv.mk_metavar(); expr m3 = uenv.mk_metavar(); expr m4 = uenv.mk_metavar(); expr F = Const("F"); expr G = Const("G"); expr f = Const("f"); expr g = Const("g"); expr a = Const("a"); expr b = Const("b"); expr x = Const("x"); expr Id = Fun({x, A}, x); expr t1 = f(m1, g(a, F)); expr t2 = f(g(a, b), Id(g(m2, m3 >> m4))); metavar_env uenv2(uenv); try { uenv2.unify(t1, t2); lean_unreachable(); } catch (exception) { // It failed because "F" is not in the set of // available definitions. } S.insert("F"); uenv.unify(t1, t2); std::cout << uenv.instantiate_metavars(t1) << "\n"; std::cout << uenv.instantiate_metavars(t2) << "\n"; } static void tst8() { environment env; elaborator elb(env); expr A = Const("A"); expr B = Const("B"); expr F = Const("F"); expr g = Const("g"); expr a = Const("a"); expr Nat = Const("Nat"); expr Real = Const("Real"); env.add_var("Nat", Type()); env.add_var("Real", Type()); env.add_var("F", Pi({{A, Type()}, {B, Type()}, {g, A >> B}}, A)); env.add_var("f", Nat >> Real); std::cout << "--------------------\n" << env << "\n"; expr _ = mk_placholder(); expr f = Const("f"); expr t = F(_,_,f); std::cout << elaborate(elb, t) << "\n"; lean_assert(elaborate(elb, t) == F(Nat, Real, f)); } static void tst9() { environment env = mk_toplevel(); elaborator elb(env); expr a = Const("a"); expr b = Const("b"); expr c = Const("c"); expr H1 = Const("H1"); expr H2 = Const("H2"); env.add_var("a", Bool); env.add_var("b", Bool); env.add_var("c", Bool); env.add_axiom("H1", Eq(a, b)); env.add_axiom("H2", Eq(b, c)); expr _ = mk_placholder(); expr t = Trans(_,_,_,_,H1,H2); expr new_t = elb(elaborate(elb, t)); std::cout << new_t << "\n"; lean_assert(new_t == Trans(Bool,a,b,c,H1,H2)); } static void tst10() { environment env = mk_toplevel(); elaborator elb(env); expr Nat = Const("Nat"); env.add_var("Nat", Type()); env.add_var("vec", Nat >> Type()); expr n = Const("n"); expr vec = Const("vec"); env.add_var("f", Pi({n, Nat}, vec(n) >> Nat)); expr f = Const("f"); expr a = Const("a"); expr b = Const("b"); expr H = Const("H"); expr fact = Const("fact"); env.add_var("a", Nat); env.add_var("b", Nat); env.add_definition("fact", Bool, Eq(a, b)); env.add_axiom("H", fact); expr _ = mk_placholder(); expr t = Congr2(_,_,_,_,f,H); std::cout << elaborate(elb, t) << "\n"; lean_assert(elaborate(elb,t) == Congr2(Nat, Fun({n,Nat}, vec(n) >> Nat), a, b, f, H)); } static void tst11() { environment env; elaborator elb(env); expr Nat = Const("Nat"); env.add_var("Nat", Type()); expr R = Const("R"); env.add_var("R", Type()); env.add_var("a", Nat); expr a = Const("a"); expr f = Const("f"); env.add_var("f", Nat >> ((R >> Nat) >> R)); expr x = Const("x"); expr y = Const("y"); expr _ = mk_placholder(); expr t = Fun({{x,_},{y,_}}, f(x, y)); std::cout << t << "\n"; std::cout << elaborate(elb, t) << "\n"; } static void tst12() { environment env; elaborator elb(env); expr A = Const("A"); expr B = Const("B"); expr a = Const("a"); expr b = Const("b"); expr f = Const("f"); expr g = Const("g"); expr Nat = Const("Nat"); env.add_var("Nat", Type()); env.add_var("f", Pi({{A,Type()},{a,A},{b,A}}, A)); env.add_var("g", Nat >> Nat); expr _ = mk_placholder(); expr t = Fun({{a,_},{b,_}},g(f(_,a,b))); std::cout << elaborate(elb, t) << "\n"; lean_assert(elaborate(elb, t) == Fun({{a,Nat},{b,Nat}},g(f(Nat,a,b)))); } static void tst13() { environment env; elaborator elb(env); expr lst = Const("list"); expr nil = Const("nil"); expr cons = Const("cons"); expr N = Const("N"); expr A = Const("A"); expr f = Const("f"); expr l = Const("l"); expr a = Const("a"); env.add_var("N", Type()); env.add_var("list", Type() >> Type()); env.add_var("nil", Pi({A, Type()}, lst(A))); env.add_var("cons", Pi({{A, Type()}, {a, A}, {l, lst(A)}}, lst(A))); env.add_var("f", lst(N>>N) >> Bool); expr _ = mk_placholder(); expr t = Fun({a,_}, f(cons(_, a, cons(_, a, nil(_))))); std::cout << elaborate(elb, t) << "\n"; } static void tst14() { environment env; elaborator elb(env); expr x = Const("x"); expr _ = mk_placholder(); expr omega = mk_app(Fun({x,_}, x(x)), Fun({x,_}, x(x))); try { elaborate(elb, omega); lean_unreachable(); } catch (exception ex) { } } int main() { tst1(); tst2(); tst3(); tst4(); tst5(); tst6(); tst7(); tst8(); tst9(); tst10(); tst11(); tst12(); tst13(); tst14(); return has_violations() ? 1 : 0; }