/* 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 #include "kernel/free_vars.h" #include "kernel/expr_sets.h" #include "kernel/replace.h" #include "kernel/metavar.h" namespace lean { /** \brief Functional object for checking whether a kernel expression has free variables or not. \remark We assume that a metavariable contains free variables. This is an approximation, since we don't know how the metavariable will be instantiated. */ class has_free_vars_fn { protected: expr_cell_offset_set m_cached; bool apply(expr const & e, unsigned offset) { // handle easy cases switch (e.kind()) { case expr_kind::Constant: if (!const_type(e)) return false; break; case expr_kind::Type: case expr_kind::Value: return false; case expr_kind::MetaVar: return true; case expr_kind::Var: return var_idx(e) >= offset; case expr_kind::App: case expr_kind::Eq: case expr_kind::Lambda: case expr_kind::Pi: case expr_kind::Let: break; } if (e.raw()->is_closed()) return false; if (offset == 0) { return apply_core(e, 0); } else { // The apply_core(e, 0) may seem redundant, but it allows us to // mark nested closed expressions. return apply_core(e, 0) && apply_core(e, offset); } } bool apply_core(expr const & e, unsigned offset) { bool shared = false; if (is_shared(e)) { shared = true; expr_cell_offset p(e.raw(), offset); if (m_cached.find(p) != m_cached.end()) return false; } bool result = false; switch (e.kind()) { case expr_kind::Constant: lean_assert(const_type(e)); result = apply(const_type(e), offset); break; case expr_kind::Type: case expr_kind::Value: case expr_kind::Var: case expr_kind::MetaVar: // easy cases were already handled lean_unreachable(); // LCOV_EXCL_LINE case expr_kind::App: result = std::any_of(begin_args(e), end_args(e), [=](expr const & arg){ return apply(arg, offset); }); break; case expr_kind::Eq: result = apply(eq_lhs(e), offset) || apply(eq_rhs(e), offset); break; case expr_kind::Lambda: case expr_kind::Pi: result = apply(abst_domain(e), offset) || apply(abst_body(e), offset + 1); break; case expr_kind::Let: result = (let_type(e) && apply(let_type(e), offset)) || apply(let_value(e), offset) || apply(let_body(e), offset + 1); break; } if (!result) { if (offset == 0) e.raw()->set_closed(); if (shared) m_cached.insert(expr_cell_offset(e.raw(), offset)); } return result; } public: has_free_vars_fn() {} bool operator()(expr const & e) { return apply(e, 0); } }; bool has_free_vars(expr const & e) { return has_free_vars_fn()(e); } /** \brief Functional object for checking whether a kernel expression has a free variable in the range [low, high) or not. \remark We assume that a metavariable contains free variables. This is an approximation, since we don't know how the metavariable will be instantiated. */ class has_free_var_in_range_fn { protected: unsigned m_low; unsigned m_high; expr_cell_offset_set m_cached; bool apply(expr const & e, unsigned offset) { // handle easy cases switch (e.kind()) { case expr_kind::Constant: if (!const_type(e)) return false; break; case expr_kind::Type: case expr_kind::Value: return false; case expr_kind::MetaVar: return true; case expr_kind::Var: return var_idx(e) >= offset + m_low && var_idx(e) < offset + m_high; case expr_kind::App: case expr_kind::Eq: case expr_kind::Lambda: case expr_kind::Pi: case expr_kind::Let: break; } if (e.raw()->is_closed()) return false; bool shared = false; if (is_shared(e)) { shared = true; expr_cell_offset p(e.raw(), offset); if (m_cached.find(p) != m_cached.end()) return false; } bool result = false; switch (e.kind()) { case expr_kind::Constant: lean_assert(const_type(e)); result = apply(const_type(e), offset); break; case expr_kind::Type: case expr_kind::Value: case expr_kind::Var: case expr_kind::MetaVar: // easy cases were already handled lean_unreachable(); // LCOV_EXCL_LINE case expr_kind::App: result = std::any_of(begin_args(e), end_args(e), [=](expr const & arg){ return apply(arg, offset); }); break; case expr_kind::Eq: result = apply(eq_lhs(e), offset) || apply(eq_rhs(e), offset); break; case expr_kind::Lambda: case expr_kind::Pi: result = apply(abst_domain(e), offset) || apply(abst_body(e), offset + 1); break; case expr_kind::Let: result = (let_type(e) && apply(let_type(e), offset)) || apply(let_value(e), offset) || apply(let_body(e), offset + 1); break; } if (!result && shared) { m_cached.insert(expr_cell_offset(e.raw(), offset)); } return result; } public: has_free_var_in_range_fn(unsigned low, unsigned high): m_low(low), m_high(high) { lean_assert(low < high); } bool operator()(expr const & e) { return apply(e, 0); } }; bool has_free_var(expr const & e, unsigned vidx) { return has_free_var_in_range_fn(vidx, vidx+1)(e); } bool has_free_var(expr const & e, unsigned low, unsigned high) { return has_free_var_in_range_fn(low, high)(e); } expr lower_free_vars(expr const & e, unsigned s, unsigned d) { lean_assert(s >= d); lean_assert(!has_free_var(e, s-d, s)); auto f = [=](expr const & e, unsigned offset) -> expr { if (is_var(e) && var_idx(e) >= s + offset) { lean_assert(var_idx(e) >= offset + d); return mk_var(var_idx(e) - d); } else if (is_metavar(e)) { lean_unreachable(); // LCOV_EXCL_LINE } else { return e; } }; return replace_fn(f)(e); } expr lift_free_vars(expr const & e, unsigned s, unsigned d) { if (d == 0) return e; auto f = [=](expr const & e, unsigned offset) -> expr { if (is_var(e) && var_idx(e) >= s + offset) { return mk_var(var_idx(e) + d); } else if (is_metavar(e)) { return add_lift(e, s + offset, d); } else { return e; } }; return replace_fn(f)(e); } }