refactor(kernel/type_checker): pass buffer<unification_constraint> as a pointer

The idea is to make it an optional parameter independent of metavar_env.

Signed-off-by: Leonardo de Moura <leonardo@microsoft.com>

src/frontends/lean/frontend_elaborator.cpp

@@ -408,7 +408,7 @@ public:
         expr new_e = preprocessor(*this)(e);
         // std::cout << "After preprocessing\n" << new_e << "\n";
         if (has_metavar(new_e)) {
-            m_type_checker.infer_type(new_e, context(), &m_menv, m_ucs);
+            m_type_checker.infer_type(new_e, context(), &m_menv, &m_ucs);
             // for (auto c : m_ucs) {
             //     formatter fmt = mk_simple_formatter();
             //     std::cout << c.pp(fmt, options(), nullptr, false) << "\n";
@@ -427,8 +427,8 @@ public:
         expr new_e = preprocessor(*this)(e);
         // std::cout << "After preprocessing\n" << new_t << "\n" << new_e << "\n";
         if (has_metavar(new_e) || has_metavar(new_t)) {
-            m_type_checker.infer_type(new_t, context(), &m_menv, m_ucs);
-            expr new_e_t = m_type_checker.infer_type(new_e, context(), &m_menv, m_ucs);
+            m_type_checker.infer_type(new_t, context(), &m_menv, &m_ucs);
+            expr new_e_t = m_type_checker.infer_type(new_e, context(), &m_menv, &m_ucs);
             m_ucs.push_back(mk_convertible_constraint(context(), new_e_t, new_t,
                                                       mk_def_type_match_justification(context(), n, e)));
             // for (auto c : m_ucs) {

src/kernel/type_checker.cpp

@@ -53,7 +53,7 @@ class type_checker::imp {
         expr r = normalize(e, ctx);
         if (is_pi(r))
             return r;
-        if (has_metavar(r) && m_menv) {
+        if (has_metavar(r) && m_menv && m_uc) {
             // Create two fresh variables A and B,
             // and assign r == (Pi(x : A), B x)
             expr A   = m_menv->mk_metavar(ctx);
@@ -76,7 +76,7 @@ class type_checker::imp {
             return u;
         if (is_bool(u))
             return Type();
-        if (has_metavar(u) && m_menv) {
+        if (has_metavar(u) && m_menv && m_uc) {
             justification jst = mk_type_expected_justification(ctx, s);
             m_uc->push_back(mk_convertible_constraint(ctx, u, TypeU, jst));
             return u;
@@ -256,7 +256,7 @@ class type_checker::imp {
         expr new_expected = normalize(expected, ctx);
         if (is_convertible_core(new_given, new_expected))
             return true;
-        if (m_menv && (has_metavar(new_given) || has_metavar(new_expected))) {
+        if (m_menv && m_uc && (has_metavar(new_given) || has_metavar(new_expected))) {
             m_uc->push_back(mk_convertible_constraint(ctx, given, expected, mk_justification()));
             return true;
         }
@@ -295,10 +295,10 @@ public:
         m_uc              = nullptr;
     }
 
-    expr infer_type(expr const & e, context const & ctx, metavar_env * menv, buffer<unification_constraint> & uc) {
+    expr infer_type(expr const & e, context const & ctx, metavar_env * menv, buffer<unification_constraint> * uc) {
         set_ctx(ctx);
         set_menv(menv);
-        flet<unification_constraints*> set_uc(m_uc, &uc);
+        flet<unification_constraints*> set_uc(m_uc, uc);
         return infer_type_core(e, ctx);
     }
 
@@ -333,12 +333,11 @@ public:
 
 type_checker::type_checker(environment const & env):m_ptr(new imp(env)) {}
 type_checker::~type_checker() {}
-expr type_checker::infer_type(expr const & e, context const & ctx, metavar_env * menv, buffer<unification_constraint> & uc) {
+expr type_checker::infer_type(expr const & e, context const & ctx, metavar_env * menv, buffer<unification_constraint> * uc) {
     return m_ptr->infer_type(e, ctx, menv, uc);
 }
 expr type_checker::infer_type(expr const & e, context const & ctx) {
-    buffer<unification_constraint> uc;
-    return infer_type(e, ctx, nullptr, uc);
+    return infer_type(e, ctx, nullptr, nullptr);
 }
 bool type_checker::is_convertible(expr const & t1, expr const & t2, context const & ctx) {
     return m_ptr->is_convertible(t1, t2, ctx);

src/kernel/type_checker.h

@@ -34,7 +34,7 @@ public:
        New metavariables and unification constraints may be created by the type checker.
        The new unification constraints are stored in \c new_constraints.
     */
-    expr infer_type(expr const & e, context const & ctx, metavar_env * menv, buffer<unification_constraint> & new_constraints);
+    expr infer_type(expr const & e, context const & ctx, metavar_env * menv, buffer<unification_constraint> * new_constraints);
 
     /**
         \brief Return the type of \c e in the context \c ctx.

src/library/elaborator/elaborator.cpp

@@ -360,7 +360,7 @@ class elaborator::imp {
         m_state.m_menv.assign(m, v, jst);
         if (menv.has_type(m)) {
             buffer<unification_constraint> ucs;
-            expr tv = m_type_inferer(v, ctx, &menv, ucs);
+            expr tv = m_type_inferer(v, ctx, &menv, &ucs);
             for (auto c : ucs)
                 push_front(c);
             justification new_jst(new typeof_mvar_justification(ctx, m, menv.get_type(m), tv, jst));
@@ -746,7 +746,7 @@ class elaborator::imp {
         buffer<expr> arg_types;
         buffer<unification_constraint> ucs;
         for (unsigned i = 1; i < num_a; i++) {
-            arg_types.push_back(m_type_inferer(arg(a, i), ctx, &menv, ucs));
+            arg_types.push_back(m_type_inferer(arg(a, i), ctx, &menv, &ucs));
             for (auto uc : ucs)
                 push_front(uc);
         }

src/library/tactic/apply_tactic.cpp

@@ -69,7 +69,7 @@ static optional<proof_state> apply_tactic(environment const & env, proof_state c
                         l.emplace_front(mvar_sol, name());
                         th_type_c = instantiate(abst_body(th_type_c), mvar_sol);
                     } else {
-                        if (inferer.is_proposition(abst_domain(th_type_c))) {
+                        if (inferer.is_proposition(abst_domain(th_type_c), context(), &new_menv)) {
                             name new_gname(gname, new_goal_idx);
                             new_goal_idx++;
                             l.emplace_front(expr(), new_gname);

src/library/type_inferer.cpp

@@ -46,7 +46,7 @@ class type_inferer::imp {
             return u;
         if (is_bool(u))
             return Type();
-        if (has_metavar(u) && m_menv) {
+        if (has_metavar(u) && m_menv && m_uc) {
             justification jst = mk_type_expected_justification(ctx, s);
             m_uc->push_back(mk_convertible_constraint(ctx, u, TypeU, jst));
             return u;
@@ -64,7 +64,7 @@ class type_inferer::imp {
                 t = m_normalizer(t, ctx);
                 if (is_pi(t)) {
                     t = abst_body(t);
-                } else if (has_metavar(t) && m_menv) {
+                } else if (has_metavar(t) && m_menv && m_uc) {
                     // Create two fresh variables A and B,
                     // and assign r == (Pi(x : A), B x)
                     expr A   = m_menv->mk_metavar(ctx);
@@ -224,10 +224,10 @@ public:
         m_uc             = nullptr;
     }
 
-    expr operator()(expr const & e, context const & ctx, metavar_env * menv, buffer<unification_constraint> & uc) {
+    expr operator()(expr const & e, context const & ctx, metavar_env * menv, buffer<unification_constraint> * uc) {
         set_ctx(ctx);
         set_menv(menv);
-        flet<unification_constraints*> set(m_uc, &uc);
+        flet<unification_constraints*> set(m_uc, uc);
         return infer_type(e, ctx);
     }
 
@@ -239,9 +239,8 @@ public:
         m_menv_timestamp = 0;
     }
 
-    bool is_proposition(expr const & e, context const & ctx) {
-        buffer<unification_constraint> uc;
-        expr t = operator()(e, ctx, nullptr, uc);
+    bool is_proposition(expr const & e, context const & ctx, metavar_env * menv) {
+        expr t = operator()(e, ctx, menv, nullptr);
         if (is_bool(t))
             return true;
         else
@@ -250,15 +249,14 @@ public:
 };
 type_inferer::type_inferer(environment const & env):m_ptr(new imp(env)) {}
 type_inferer::~type_inferer() {}
-expr type_inferer::operator()(expr const & e, context const & ctx, metavar_env * menv, buffer<unification_constraint> & uc) {
+expr type_inferer::operator()(expr const & e, context const & ctx, metavar_env * menv, buffer<unification_constraint> * uc) {
     return m_ptr->operator()(e, ctx, menv, uc);
 }
 expr type_inferer::operator()(expr const & e, context const & ctx) {
-    buffer<unification_constraint> uc;
-    return operator()(e, ctx, nullptr, uc);
+    return operator()(e, ctx, nullptr, nullptr);
 }
-bool type_inferer::is_proposition(expr const & e, context const & ctx) {
-    return m_ptr->is_proposition(e, ctx);
+bool type_inferer::is_proposition(expr const & e, context const & ctx, metavar_env * menv) {
+    return m_ptr->is_proposition(e, ctx, menv);
 }
 void type_inferer::clear() { m_ptr->clear(); }
 

src/library/type_inferer.h

@@ -31,9 +31,9 @@ public:
     type_inferer(environment const & env);
     ~type_inferer();
 
-    expr operator()(expr const & e, context const & ctx, metavar_env * menv, buffer<unification_constraint> & uc);
+    expr operator()(expr const & e, context const & ctx, metavar_env * menv, buffer<unification_constraint> * uc);
     expr operator()(expr const & e, context const & ctx = context());
-    bool is_proposition(expr const & e, context const & ctx = context());
+    bool is_proposition(expr const & e, context const & ctx = context(), metavar_env * menv = nullptr);
     void clear();
 };
 

src/tests/kernel/metavar.cpp

@@ -474,7 +474,7 @@ static void tst23() {
     buffer<unification_constraint> up;
     std::cout << F1 << "\n";
     try {
-        std::cout << checker.infer_type(F1, context(), &menv, up) << "\n";
+        std::cout << checker.infer_type(F1, context(), &menv, &up) << "\n";
     } catch (kernel_exception & ex) {
         formatter fmt = mk_simple_formatter();
         io_state st(options(), fmt);
@@ -508,7 +508,7 @@ static void tst25() {
     env.add_var("b", N);
     expr m = menv.mk_metavar();
     expr F = m(a, b);
-    std::cout << checker.infer_type(F, context(), &menv, up) << "\n";
+    std::cout << checker.infer_type(F, context(), &menv, &up) << "\n";
     std::cout << menv << "\n";
     std::cout << up << "\n";
 }
@@ -554,7 +554,7 @@ static void tst26() {
     expr A4 = menv.mk_metavar();
     expr F  = cons(A1, m1(a), cons(A2, m2(n), cons(A3, m3(b), nil(A4))));
     std::cout << F << "\n";
-    std::cout << checker.infer_type(F, context(), &menv, up) << "\n";
+    std::cout << checker.infer_type(F, context(), &menv, &up) << "\n";
     std::cout << menv << "\n";
     std::cout << up << "\n";
 }
@@ -588,7 +588,7 @@ static void tst27() {
     expr m2 = menv.mk_metavar();
     expr F = Fun({{x, T1}, {y, T2}}, f(A1, x, y))(m1(a), m2(b));
     std::cout << F << "\n";
-    std::cout << checker.infer_type(F, context(), &menv, up) << "\n";
+    std::cout << checker.infer_type(F, context(), &menv, &up) << "\n";
     std::cout << menv << "\n";
     std::cout << up << "\n";
 }

src/tests/library/elaborator/elaborator.cpp

@@ -48,7 +48,7 @@ static void tst1() {
     expr A4 = menv.mk_metavar();
     expr F  = cons(A1, m1(a), cons(A2, m2(n), cons(A3, m3(b), nil(A4))));
     std::cout << F << "\n";
-    std::cout << checker.infer_type(F, context(), &menv, ucs) << "\n";
+    std::cout << checker.infer_type(F, context(), &menv, &ucs) << "\n";
     expr int_id = Fun({a, Int}, a);
     expr nat_id = Fun({a, Nat}, a);
     ucs.push_back(mk_choice_constraint(context(), m1, { int_id, mk_int_to_real_fn() }, justification()));
@@ -92,7 +92,7 @@ static void tst2() {
     expr nat_id = Fun({a, Nat}, a);
     expr F  = m1(g(m2, m3(a)), m4(nVal(0)));
     std::cout << F << "\n";
-    std::cout << checker.infer_type(F, context(), &menv, ucs) << "\n";
+    std::cout << checker.infer_type(F, context(), &menv, &ucs) << "\n";
     ucs.push_back(mk_choice_constraint(context(), m1, { mk_nat_le_fn(), mk_int_le_fn(), mk_real_le_fn() }, justification()));
     ucs.push_back(mk_choice_constraint(context(), m3, { int_id, mk_int_to_real_fn() }, justification()));
     ucs.push_back(mk_choice_constraint(context(), m4, { nat_id, mk_nat_to_int_fn(), mk_nat_to_real_fn() }, justification()));
@@ -135,7 +135,7 @@ static void tst3() {
     expr x = Const("x");
     expr F = Fun({x, m1}, m2(f(m3, x), m4(nVal(10))))(m5(a));
     std::cout << F << "\n";
-    std::cout << checker.infer_type(F, context(), &menv, ucs) << "\n";
+    std::cout << checker.infer_type(F, context(), &menv, &ucs) << "\n";
     ucs.push_back(mk_choice_constraint(context(), m2, { mk_nat_le_fn(), mk_int_le_fn(), mk_real_le_fn() }, justification()));
     ucs.push_back(mk_choice_constraint(context(), m4, { nat_id, mk_nat_to_int_fn(), mk_nat_to_real_fn() }, justification()));
     ucs.push_back(mk_choice_constraint(context(), m5, { int_id, mk_int_to_real_fn() }, justification()));
@@ -180,7 +180,7 @@ static void tst4() {
     expr int_id = Fun({a, Int}, a);
     expr F = Fun({{x, m1}, {y, m2}}, m3(f(m4, x), f(m5, y)))(m6(a), b);
     std::cout << F << "\n";
-    std::cout << checker.infer_type(F, context(), &menv, ucs) << "\n";
+    std::cout << checker.infer_type(F, context(), &menv, &ucs) << "\n";
     ucs.push_back(mk_choice_constraint(context(), m3, { mk_nat_le_fn(), mk_int_le_fn(), mk_real_le_fn() }, justification()));
     ucs.push_back(mk_choice_constraint(context(), m6, { int_id, mk_int_to_real_fn() }, justification()));
     elaborator elb(env, menv, ucs.size(), ucs.data());
@@ -222,7 +222,7 @@ static void tst5() {
     expr int_id = Fun({a, Int}, a);
     expr F = Fun({{x, m1}, {y, m2}}, f(m3, x, y))(m4(a), b);
     std::cout << F << "\n";
-    std::cout << checker.infer_type(F, context(), &menv, ucs) << "\n";
+    std::cout << checker.infer_type(F, context(), &menv, &ucs) << "\n";
     ucs.push_back(mk_choice_constraint(context(), m4, { int_id, mk_int_to_real_fn() }, justification()));
     elaborator elb(env, menv, ucs.size(), ucs.data());
     elb.next();
@@ -259,7 +259,7 @@ static void tst6() {
     env.add_axiom("H2", Eq(a, b));
     expr V = Subst(m1, m2, m3, m4, H1, H2);
     expr expected = Eq(f(a, f(b, b)), a);
-    expr given    = checker.infer_type(V, context(), &menv, ucs);
+    expr given    = checker.infer_type(V, context(), &menv, &ucs);
     ucs.push_back(mk_eq_constraint(context(), expected, given, justification()));
     elaborator elb(env, menv, ucs.size(), ucs.data());
     metavar_env s = elb.next();
@@ -273,7 +273,7 @@ static expr elaborate(expr const & e, environment const & env) {
     buffer<unification_constraint> ucs;
     type_checker checker(env);
     expr e2 = replace_placeholders_with_metavars(e, menv);
-    checker.infer_type(e2, context(), &menv, ucs);
+    checker.infer_type(e2, context(), &menv, &ucs);
     elaborator elb(env, menv, ucs.size(), ucs.data());
     metavar_env s = elb.next();
     return instantiate_metavars(e2, s);
@@ -830,7 +830,7 @@ void tst26() {
     expr m1 = menv.mk_metavar();
     expr F  = Eq(g(m1, a), a);
     std::cout << F << "\n";
-    std::cout << checker.infer_type(F, context(), &menv, ucs) << "\n";
+    std::cout << checker.infer_type(F, context(), &menv, &ucs) << "\n";
     elaborator elb(env, menv, ucs.size(), ucs.data());
     metavar_env s = elb.next();
     std::cout << instantiate_metavars(F, s) << "\n";
@@ -865,7 +865,7 @@ void tst27() {
     expr m3 = menv.mk_metavar();
     expr F  = Fun({f, m1}, eq(m2, g(m3, f)(a), a));
     std::cout << F << "\n";
-    std::cout << checker.infer_type(F, context(), &menv, ucs) << "\n";
+    std::cout << checker.infer_type(F, context(), &menv, &ucs) << "\n";
     elaborator elb(env, menv, ucs.size(), ucs.data());
     metavar_env s = elb.next();
     std::cout << instantiate_metavars(F, s) << "\n";

src/tests/library/type_inferer.cpp

@@ -133,7 +133,7 @@ static void tst4() {
     expr A4 = menv.mk_metavar();
     expr F  = cons(A1, m1(a), cons(A2, m2(n), cons(A3, m3(b), nil(A4))));
     std::cout << F << "\n";
-    std::cout << inferer(F, context(), &menv, uc) << "\n";
+    std::cout << inferer(F, context(), &menv, &uc) << "\n";
     std::cout << uc << "\n";
 }