// Formatting library for C++ - format string compilation // // Copyright (c) 2012 - present, Victor Zverovich and fmt contributors // All rights reserved. // // For the license information refer to format.h. #ifndef FMT_PREPARE_H_ #define FMT_PREPARE_H_ #ifndef FMT_HAS_CONSTRUCTIBLE_TRAITS # define FMT_HAS_CONSTRUCTIBLE_TRAITS \ (FMT_GCC_VERSION >= 407 || FMT_CLANG_VERSION || FMT_MSC_VER) #endif #include "format.h" #include FMT_BEGIN_NAMESPACE template struct format_part { public: struct named_argument_id { FMT_CONSTEXPR named_argument_id(internal::string_view_metadata id) : id(id) {} internal::string_view_metadata id; }; struct argument_id { FMT_CONSTEXPR argument_id() : argument_id(0u) {} FMT_CONSTEXPR argument_id(unsigned id) : which(which_arg_id::index), val(id) {} FMT_CONSTEXPR argument_id(internal::string_view_metadata id) : which(which_arg_id::named_index), val(id) {} enum class which_arg_id { index, named_index }; which_arg_id which; FMT_UNRESTRICTED_UNION value { FMT_CONSTEXPR value() : index(0u) {} FMT_CONSTEXPR value(unsigned id) : index(id) {} FMT_CONSTEXPR value(internal::string_view_metadata id) : named_index(id) {} unsigned index; internal::string_view_metadata named_index; } val; }; struct specification { FMT_CONSTEXPR specification() : arg_id(0u) {} FMT_CONSTEXPR specification(unsigned id) : arg_id(id) {} FMT_CONSTEXPR specification(internal::string_view_metadata id) : arg_id(id) {} argument_id arg_id; internal::dynamic_format_specs parsed_specs; }; FMT_CONSTEXPR format_part() : which(which_value::argument_id), end_of_argument_id(0u), val(0u) {} FMT_CONSTEXPR format_part(internal::string_view_metadata text) : which(which_value::text), end_of_argument_id(0u), val(text) {} FMT_CONSTEXPR format_part(unsigned id) : which(which_value::argument_id), end_of_argument_id(0u), val(id) {} FMT_CONSTEXPR format_part(named_argument_id arg_id) : which(which_value::named_argument_id), end_of_argument_id(0u), val(arg_id) {} FMT_CONSTEXPR format_part(specification spec) : which(which_value::specification), end_of_argument_id(0u), val(spec) {} enum class which_value { argument_id, named_argument_id, text, specification }; which_value which; std::size_t end_of_argument_id; FMT_UNRESTRICTED_UNION value { FMT_CONSTEXPR value() : arg_id(0u) {} FMT_CONSTEXPR value(unsigned id) : arg_id(id) {} FMT_CONSTEXPR value(named_argument_id named_id) : named_arg_id(named_id.id) {} FMT_CONSTEXPR value(internal::string_view_metadata t) : text(t) {} FMT_CONSTEXPR value(specification s) : spec(s) {} unsigned arg_id; internal::string_view_metadata named_arg_id; internal::string_view_metadata text; specification spec; } val; }; namespace internal { template class format_preparation_handler : public internal::error_handler { private: typedef format_part part; public: typedef internal::null_terminating_iterator iterator; FMT_CONSTEXPR format_preparation_handler(basic_string_view format, PartsContainer& parts) : parts_(parts), format_(format), parse_context_(format) {} FMT_CONSTEXPR void on_text(const Char* begin, const Char* end) { if (begin == end) { return; } const auto offset = begin - format_.data(); const auto size = end - begin; parts_.add(part(string_view_metadata(offset, size))); } FMT_CONSTEXPR void on_arg_id() { parts_.add(part(parse_context_.next_arg_id())); } FMT_CONSTEXPR void on_arg_id(unsigned id) { parse_context_.check_arg_id(id); parts_.add(part(id)); } FMT_CONSTEXPR void on_arg_id(basic_string_view id) { const auto view = string_view_metadata(format_, id); const auto arg_id = typename part::named_argument_id(view); parts_.add(part(arg_id)); } FMT_CONSTEXPR void on_replacement_field(const Char* ptr) { auto last_part = parts_.last(); last_part.end_of_argument_id = ptr - format_.begin(); parts_.substitute_last(last_part); } FMT_CONSTEXPR const Char* on_format_specs(const Char* begin, const Char* end) { const auto specs_offset = to_unsigned(begin - format_.begin()); typedef basic_parse_context parse_context; internal::dynamic_format_specs parsed_specs; dynamic_specs_handler handler(parsed_specs, parse_context_); begin = parse_format_specs(begin, end, handler); if (*begin != '}') { on_error("missing '}' in format string"); } const auto last_part = parts_.last(); auto specs = last_part.which == part::which_value::argument_id ? typename part::specification(last_part.val.arg_id) : typename part::specification(last_part.val.named_arg_id); specs.parsed_specs = parsed_specs; auto new_part = part(specs); new_part.end_of_argument_id = specs_offset; parts_.substitute_last(new_part); return begin; } private: PartsContainer& parts_; basic_string_view format_; basic_parse_context parse_context_; }; template class prepared_format { public: using char_type = char_t; using format_part_t = format_part; prepared_format(Format f) : format_(std::move(f)), parts_provider_(to_string_view(format_)) {} prepared_format() = delete; std::size_t formatted_size(const Args&... args) const { const auto it = this->format_to(counting_iterator(), args...); return it.count(); } template ::value)> inline format_to_n_result format_to_n(OutputIt out, unsigned n, const Args&... args) const { format_arg_store::type, Args...> as(args...); typedef truncating_iterator trunc_it; typedef output_range range; range r(trunc_it(out, n)); auto it = this->vformat_to( r, typename format_to_n_args::type(as)); return {it.base(), it.count()}; } std::basic_string format(const Args&... args) const { basic_memory_buffer buffer; typedef back_insert_range> range; this->vformat_to(range(buffer), make_args_checked(format_, args...)); return to_string(buffer); } template ::value)> inline std::back_insert_iterator format_to( std::back_insert_iterator out, const Args&... args) const { internal::container_buffer buffer(internal::get_container(out)); typedef back_insert_range> range; this->vformat_to(range(buffer), make_args_checked(format_, args...)); return out; } template inline OutputIt format_to(OutputIt out, const Args&... args) const { typedef typename format_context_t::type context; typedef output_range range; format_arg_store as(args...); return this->vformat_to(range(out), basic_format_args(as)); } template inline typename buffer_context::iterator format_to( basic_memory_buffer& buf, const Args&... args) const { typedef back_insert_range> range; return this->vformat_to(range(buf), make_args_checked(format_, args...)); } private: typedef buffer_context context; template typename context::iterator vformat_to(Range out, basic_format_args args) const { const auto format_view = internal::to_string_view(format_); basic_parse_context parse_ctx(format_view); context ctx(out.begin(), args); const auto& parts = parts_provider_.parts(); for (auto part_it = parts.begin(); part_it != parts.end(); ++part_it) { const auto& part = *part_it; const auto& value = part.val; switch (part.which) { case format_part_t::which_value::text: { const auto text = value.text.to_view(format_view.data()); auto output = ctx.out(); auto&& it = internal::reserve(output, text.size()); it = std::copy_n(text.begin(), text.size(), it); ctx.advance_to(output); } break; case format_part_t::which_value::argument_id: { advance_parse_context_to_specification(parse_ctx, part); format_arg(parse_ctx, ctx, value.arg_id); } break; case format_part_t::which_value::named_argument_id: { advance_parse_context_to_specification(parse_ctx, part); const auto named_arg_id = value.named_arg_id.to_view(format_view.data()); format_arg(parse_ctx, ctx, named_arg_id); } break; case format_part_t::which_value::specification: { const auto& arg_id_value = value.spec.arg_id.val; const auto arg = value.spec.arg_id.which == format_part_t::argument_id::which_arg_id::index ? ctx.arg(arg_id_value.index) : ctx.arg(arg_id_value.named_index.to_view( to_string_view(format_).data())); auto specs = value.spec.parsed_specs; handle_dynamic_spec( specs.width_, specs.width_ref, ctx, format_view.begin()); handle_dynamic_spec( specs.precision, specs.precision_ref, ctx, format_view.begin()); check_prepared_specs(specs, arg.type()); advance_parse_context_to_specification(parse_ctx, part); ctx.advance_to( visit_format_arg(arg_formatter(ctx, nullptr, &specs), arg)); } break; } } return ctx.out(); } void advance_parse_context_to_specification( basic_parse_context& parse_ctx, const format_part_t& part) const { const auto view = to_string_view(format_); const auto specification_begin = view.data() + part.end_of_argument_id; advance_to(parse_ctx, specification_begin); } template void format_arg(basic_parse_context& parse_ctx, Context& ctx, Id arg_id) const { parse_ctx.check_arg_id(arg_id); const auto stopped_at = visit_format_arg(arg_formatter(ctx), ctx.arg(arg_id)); ctx.advance_to(stopped_at); } template void check_prepared_specs(const basic_format_specs& specs, internal::type arg_type) const { internal::error_handler h; numeric_specs_checker checker(h, arg_type); if (specs.align_ == ALIGN_NUMERIC) { checker.require_numeric_argument(); } if (specs.has(PLUS_FLAG | MINUS_FLAG | SIGN_FLAG)) { checker.check_sign(); } if (specs.has(HASH_FLAG)) { checker.require_numeric_argument(); } if (specs.has_precision()) { checker.check_precision(); } } private: Format format_; PreparedPartsProvider parts_provider_; }; template class compiletime_prepared_parts_type_provider { private: using char_type = char_t; class count_handler { private: typedef internal::null_terminating_iterator iterator; public: FMT_CONSTEXPR count_handler() : counter_(0u) {} FMT_CONSTEXPR void on_text(const char_type* begin, const char_type* end) { if (begin != end) { ++counter_; } } FMT_CONSTEXPR void on_arg_id() { ++counter_; } FMT_CONSTEXPR void on_arg_id(unsigned) { ++counter_; } FMT_CONSTEXPR void on_arg_id(basic_string_view) { ++counter_; } FMT_CONSTEXPR void on_replacement_field(const char_type*) {} FMT_CONSTEXPR const char_type* on_format_specs(const char_type* begin, const char_type* end) { return find_matching_brace(begin, end); } FMT_CONSTEXPR void on_error(const char*) {} FMT_CONSTEXPR unsigned result() const { return counter_; } private: FMT_CONSTEXPR const char_type* find_matching_brace(const char_type* begin, const char_type* end) { unsigned braces_counter{0u}; for (; begin != end; ++begin) { if (*begin == '{') { ++braces_counter; } else if (*begin == '}') { if (braces_counter == 0u) { break; } --braces_counter; } } return begin; } private: unsigned counter_; }; static FMT_CONSTEXPR unsigned count_parts() { FMT_CONSTEXPR_DECL const auto text = to_string_view(Format{}); count_handler handler; internal::parse_format_string(text, handler); return handler.result(); } // Workaround for old compilers. Compiletime parts preparation will not be // performed with them anyway. #if FMT_USE_CONSTEXPR static FMT_CONSTEXPR_DECL const unsigned number_of_format_parts = compiletime_prepared_parts_type_provider::count_parts(); #else static const unsigned number_of_format_parts = 0u; #endif public: template struct format_parts_array { typedef format_part value_type; FMT_CONSTEXPR format_parts_array() : arr{} {} FMT_CONSTEXPR value_type& operator[](unsigned ind) { return arr[ind]; } FMT_CONSTEXPR const value_type* begin() const { return arr; } FMT_CONSTEXPR const value_type* end() const { return begin() + N; } private: value_type arr[N]; }; struct empty { // Parts preparator will search for it typedef format_part value_type; }; using type = conditional_t(number_of_format_parts), format_parts_array, empty>; }; template class compiletime_prepared_parts_collector { private: typedef typename Parts::value_type format_part; public: FMT_CONSTEXPR explicit compiletime_prepared_parts_collector(Parts& parts) : parts_{parts}, counter_{0u} {} FMT_CONSTEXPR void add(format_part part) { parts_[counter_++] = part; } FMT_CONSTEXPR void substitute_last(format_part part) { parts_[counter_ - 1] = part; } FMT_CONSTEXPR format_part last() { return parts_[counter_ - 1]; } private: Parts& parts_; unsigned counter_; }; template FMT_CONSTEXPR PartsContainer prepare_parts(basic_string_view format) { PartsContainer parts; internal::parse_format_string( format, format_preparation_handler(format, parts)); return parts; } template FMT_CONSTEXPR PartsContainer prepare_compiletime_parts(basic_string_view format) { typedef compiletime_prepared_parts_collector collector; PartsContainer parts; collector c(parts); internal::parse_format_string( format, format_preparation_handler(format, c)); return parts; } template class runtime_parts_provider { public: runtime_parts_provider() = delete; template runtime_parts_provider(basic_string_view format) : parts_(prepare_parts(format)) {} const PartsContainer& parts() const { return parts_; } private: PartsContainer parts_; }; template struct compiletime_parts_provider { compiletime_parts_provider() = delete; template FMT_CONSTEXPR compiletime_parts_provider(basic_string_view) {} const PartsContainer& parts() const { static FMT_CONSTEXPR_DECL const PartsContainer prepared_parts = prepare_compiletime_parts( internal::to_string_view(Format{})); return prepared_parts; } }; template struct parts_container_concept_check : std::true_type { #if FMT_HAS_CONSTRUCTIBLE_TRAITS static_assert(std::is_copy_constructible::value, "PartsContainer is not copy constructible"); static_assert(std::is_move_constructible::value, "PartsContainer is not move constructible"); #endif template struct has_format_part_type : std::false_type {}; template struct has_format_part_type< T, typename void_::type> : std::true_type { }; static_assert(has_format_part_type::value, "PartsContainer doesn't provide format_part_type typedef"); struct check_second {}; struct check_first : check_second {}; template static std::false_type has_add_check(check_second); template static decltype( (void)std::declval().add(std::declval()), std::true_type()) has_add_check(check_first); typedef decltype(has_add_check(check_first())) has_add; static_assert(has_add::value, "PartsContainer doesn't provide add() method"); template static std::false_type has_last_check(check_second); template static decltype((void)std::declval().last(), std::true_type()) has_last_check(check_first); typedef decltype(has_last_check(check_first())) has_last; static_assert(has_last::value, "PartsContainer doesn't provide last() method"); template static std::false_type has_substitute_last_check(check_second); template static decltype((void)std::declval().substitute_last( std::declval()), std::true_type()) has_substitute_last_check(check_first); typedef decltype(has_substitute_last_check( check_first())) has_substitute_last; static_assert(has_substitute_last::value, "PartsContainer doesn't provide substitute_last() method"); template static std::false_type has_begin_check(check_second); template static decltype((void)std::declval().begin(), std::true_type()) has_begin_check(check_first); typedef decltype(has_begin_check(check_first())) has_begin; static_assert(has_begin::value, "PartsContainer doesn't provide begin() method"); template static std::false_type has_end_check(check_second); template static decltype((void)std::declval().end(), std::true_type()) has_end_check(check_first); typedef decltype(has_end_check(check_first())) has_end; static_assert(has_end::value, "PartsContainer doesn't provide end() method"); }; template struct parts_provider_type { typedef compiletime_parts_provider< Format, typename compiletime_prepared_parts_type_provider::type> type; }; template struct parts_provider_type { static_assert(parts_container_concept_check::value, "Parts container doesn't meet the concept"); typedef runtime_parts_provider type; }; template struct basic_prepared_format { typedef internal::prepared_format::value, Format, PreparedPartsContainer>::type, Args...> type; }; template std::basic_string to_runtime_format(basic_string_view format) { return std::basic_string(format.begin(), format.size()); } template std::basic_string to_runtime_format(const Char* format) { return std::basic_string(format); } template >> class parts_container { public: typedef format_part format_part_type; void add(format_part_type part) { parts_.push_back(std::move(part)); } void substitute_last(format_part_type part) { parts_.back() = std::move(part); } format_part_type last() { return parts_.back(); } auto begin() -> decltype(std::declval().begin()) { return parts_.begin(); } auto begin() const -> decltype(std::declval().begin()) { return parts_.begin(); } auto end() -> decltype(std::declval().end()) { return parts_.end(); } auto end() const -> decltype(std::declval().end()) { return parts_.end(); } private: Container parts_; }; // Delegate preparing to preparator, to take advantage of a partial // specialization. template struct preparator { typedef parts_container> container; typedef typename basic_prepared_format::type prepared_format_type; static auto prepare(Format format) -> prepared_format_type { return prepared_format_type(std::move(format)); } }; template struct preparator> { typedef prepared_format prepared_format_type; static auto prepare(PassedFormat format) -> prepared_format_type { return prepared_format_type(std::move(format)); } }; struct compiletime_format_tag {}; struct runtime_format_tag {}; template struct format_tag { using type = conditional_t::value, compiletime_format_tag, runtime_format_tag>; }; #if FMT_USE_CONSTEXPR template auto do_prepare(runtime_format_tag, Format format) { return preparator::prepare(std::move(format)); } template FMT_CONSTEXPR auto do_prepare(compiletime_format_tag, const Format& format) { return typename basic_prepared_format::type(format); } #else template auto do_prepare(const Format& format) -> decltype(preparator::prepare(format)) { return preparator::prepare(format); } #endif } // namespace internal template >> struct parts_container { typedef internal::parts_container type; }; template struct basic_prepared_format { typedef typename internal::basic_prepared_format::type type; }; template struct prepared_format { typedef typename basic_prepared_format< std::string, typename parts_container::type, Args...>::type type; }; template struct wprepared_format { typedef typename basic_prepared_format::type, Args...>::type type; }; #if FMT_USE_ALIAS_TEMPLATES template >> using parts_container_t = typename parts_container::type; template using basic_prepared_format_t = typename basic_prepared_format::type; template using prepared_format_t = basic_prepared_format_t, Args...>; template using wprepared_format_t = basic_prepared_format_t, Args...>; #endif #if FMT_USE_CONSTEXPR template FMT_CONSTEXPR auto prepare(Format format) { return internal::do_prepare( typename internal::format_tag::type{}, std::move(format)); } #else template auto prepare(Format format) -> typename internal::preparator::prepared_format_type { return internal::preparator::prepare(std::move(format)); } #endif template auto prepare(const Char* format) -> typename internal::preparator, Args...>::prepared_format_type { return prepare(internal::to_runtime_format(format)); } template auto prepare(const Char(format)[N]) -> typename internal::preparator, Args...>::prepared_format_type { const auto view = basic_string_view(format, N); return prepare(internal::to_runtime_format(view)); } template auto prepare(basic_string_view format) -> typename internal::preparator, Args...>::prepared_format_type { return prepare(internal::to_runtime_format(format)); } FMT_END_NAMESPACE #endif // FMT_PREPARE_H_