/* Copyright (c) 2016 Microsoft Corporation. All rights reserved. Released under Apache 2.0 license as described in the file LICENSE. Author: Leonardo de Moura */ #include #include "util/sstream.h" #include "library/kernel_serializer.h" #include "frontends/lean/parser.h" #include "frontends/lean/tokens.h" namespace lean { static name * g_structure_instance_name = nullptr; static std::string * g_structure_instance_opcode = nullptr; [[ noreturn ]] static void throw_se_ex() { throw exception("unexpected occurrence of 'structure instance' expression"); } /* We encode a 'structure instance' expression using a macro. This is a trick to avoid creating a new kind of expression. 'Structure instance' expressions are temporary objects used by the elaborator. Example: Given structure point (A B : Type) := (x : A) (y : B) the structure instance { point, x := 10, y := 20 } is compiled into point.mk 10 20 */ class structure_instance_macro_cell : public macro_definition_cell { name m_struct; list m_fields; public: structure_instance_macro_cell(name const & s, list const & fs): m_struct(s), m_fields(fs) {} virtual name get_name() const { return *g_structure_instance_name; } virtual expr check_type(expr const &, abstract_type_context &, bool) const { throw_se_ex(); } virtual optional expand(expr const &, abstract_type_context &) const { throw_se_ex(); } virtual void write(serializer & s) const { s << *g_structure_instance_opcode << m_struct; write_list(s, m_fields); } name const & get_struct() const { return m_struct; } list const & get_field_names() const { return m_fields; } }; static expr mk_structure_instance_core(name const & s, list const & fs, unsigned num, expr const * args) { lean_assert(num == length(fs) || num == length(fs) + 1); macro_definition def(new structure_instance_macro_cell(s, fs)); return mk_macro(def, num, args); } expr mk_structure_instance(name const & s, buffer const & fns, buffer const & fvs) { lean_assert(fns.size() == fvs.size()); return mk_structure_instance_core(s, to_list(fns), fvs.size(), fvs.data()); } expr mk_structure_instance(expr const & src, buffer const & fns, buffer const & fvs) { buffer aux; aux.append(fvs); aux.push_back(src); return mk_structure_instance_core(name(), to_list(fns), aux.size(), aux.data()); } bool is_structure_instance(expr const & e) { return is_macro(e) && macro_def(e).get_name() == *g_structure_instance_name; } void get_structure_instance_info(expr const & e, name & struct_name, optional & source, buffer & field_names, buffer & field_values) { lean_assert(is_structure_instance(e)); struct_name = static_cast(macro_def(e).raw())->get_struct(); list const & fns = static_cast(macro_def(e).raw())->get_field_names(); to_buffer(fns, field_names); unsigned num_fields = field_names.size(); lean_assert(macro_num_args(e) == num_fields || macro_num_args(e) == num_fields+1); if (num_fields < macro_num_args(e)) source = macro_arg(e, num_fields); for (unsigned i = 0; i < num_fields; i++) field_values.push_back(macro_arg(e, i)); } void initialize_structure_instance() { g_structure_instance_name = new name("structure instance"); g_structure_instance_opcode = new std::string("STI"); register_macro_deserializer(*g_structure_instance_opcode, [](deserializer & d, unsigned num, expr const * args) { list fns; name s; d >> s; fns = read_list(d); unsigned len = length(fns); if (num != len + 1 && num != len) throw corrupted_stream_exception(); return mk_structure_instance_core(s, fns, num, args); }); } void finalize_structure_instance() { delete g_structure_instance_opcode; delete g_structure_instance_name; } }