// -*- C++ -*- //===----------------------------------------------------------------------===// // // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions. // See https://llvm.org/LICENSE.txt for license information. // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception // //===----------------------------------------------------------------------===// #ifndef _LIBCPP___FORMAT_RANGE_FORMATTER_H #define _LIBCPP___FORMAT_RANGE_FORMATTER_H #if !defined(_LIBCPP_HAS_NO_PRAGMA_SYSTEM_HEADER) # pragma GCC system_header #endif #include <__algorithm/ranges_copy.h> #include <__chrono/statically_widen.h> #include <__concepts/same_as.h> #include <__config> #include <__format/buffer.h> #include <__format/concepts.h> #include <__format/format_context.h> #include <__format/format_error.h> #include <__format/formatter.h> #include <__format/formatter_output.h> #include <__format/parser_std_format_spec.h> #include <__iterator/back_insert_iterator.h> #include <__ranges/concepts.h> #include <__ranges/data.h> #include <__ranges/from_range.h> #include <__ranges/size.h> #include <__type_traits/remove_cvref.h> #include _LIBCPP_BEGIN_NAMESPACE_STD #if _LIBCPP_STD_VER >= 23 template requires same_as, _Tp> && formattable<_Tp, _CharT> struct _LIBCPP_TEMPLATE_VIS range_formatter { _LIBCPP_HIDE_FROM_ABI constexpr void set_separator(basic_string_view<_CharT> __separator) noexcept { __separator_ = __separator; } _LIBCPP_HIDE_FROM_ABI constexpr void set_brackets(basic_string_view<_CharT> __opening_bracket, basic_string_view<_CharT> __closing_bracket) noexcept { __opening_bracket_ = __opening_bracket; __closing_bracket_ = __closing_bracket; } _LIBCPP_HIDE_FROM_ABI constexpr formatter<_Tp, _CharT>& underlying() noexcept { return __underlying_; } _LIBCPP_HIDE_FROM_ABI constexpr const formatter<_Tp, _CharT>& underlying() const noexcept { return __underlying_; } template _LIBCPP_HIDE_FROM_ABI constexpr typename _ParseContext::iterator parse(_ParseContext& __ctx) { auto __begin = __parser_.__parse(__ctx, __format_spec::__fields_range); auto __end = __ctx.end(); // Note the cases where __begin == __end in this code only happens when the // replacement-field has no terminating }, or when the parse is manually // called with a format-spec. The former is an error and the latter means // using a formatter without the format functions or print. if (__begin == __end) [[unlikely]] return __parse_empty_range_underlying_spec(__ctx, __begin); // The n field overrides a possible m type, therefore delay applying the // effect of n until the type has been procesed. __parse_type(__begin, __end); if (__parser_.__clear_brackets_) set_brackets({}, {}); if (__begin == __end) [[unlikely]] return __parse_empty_range_underlying_spec(__ctx, __begin); bool __has_range_underlying_spec = *__begin == _CharT(':'); if (__has_range_underlying_spec) { // range-underlying-spec: // : format-spec ++__begin; } else if (__begin != __end && *__begin != _CharT('}')) // When there is no underlaying range the current parse should have // consumed the format-spec. If not, the not consumed input will be // processed by the underlying. For example {:-} for a range in invalid, // the sign field is not present. Without this check the underlying_ will // get -} as input which my be valid. std::__throw_format_error("The format specifier should consume the input or end with a '}'"); __ctx.advance_to(__begin); __begin = __underlying_.parse(__ctx); // This test should not be required if __has_range_underlying_spec is false. // However this test makes sure the underlying formatter left the parser in // a valid state. (Note this is not a full protection against evil parsers. // For example // } this is test for the next argument {} // ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~^ // could consume more than it should. if (__begin != __end && *__begin != _CharT('}')) std::__throw_format_error("The format specifier should consume the input or end with a '}'"); if (__parser_.__type_ != __format_spec::__type::__default) { // [format.range.formatter]/6 // If the range-type is s or ?s, then there shall be no n option and no // range-underlying-spec. if (__parser_.__clear_brackets_) { if (__parser_.__type_ == __format_spec::__type::__string) std::__throw_format_error("The n option and type s can't be used together"); std::__throw_format_error("The n option and type ?s can't be used together"); } if (__has_range_underlying_spec) { if (__parser_.__type_ == __format_spec::__type::__string) std::__throw_format_error("Type s and an underlying format specification can't be used together"); std::__throw_format_error("Type ?s and an underlying format specification can't be used together"); } } else if (!__has_range_underlying_spec) std::__set_debug_format(__underlying_); return __begin; } template requires formattable, _CharT> && same_as>, _Tp> _LIBCPP_HIDE_FROM_ABI typename _FormatContext::iterator format(_Rp&& __range, _FormatContext& __ctx) const { __format_spec::__parsed_specifications<_CharT> __specs = __parser_.__get_parsed_std_specifications(__ctx); if (!__specs.__has_width()) return __format_range(__range, __ctx, __specs); // The size of the buffer needed is: // - open bracket characters // - close bracket character // - n elements where every element may have a different size // - (n -1) separators // The size of the element is hard to predict, knowing the type helps but // it depends on the format-spec. As an initial estimate we guess 6 // characters. // Typically both brackets are 1 character and the separator is 2 // characters. Which means there will be // (n - 1) * 2 + 1 + 1 = n * 2 character // So estimate 8 times the range size as buffer. std::size_t __capacity_hint = 0; if constexpr (std::ranges::sized_range<_Rp>) __capacity_hint = 8 * ranges::size(__range); __format::__retarget_buffer<_CharT> __buffer{__capacity_hint}; basic_format_context::__iterator, _CharT> __c{ __buffer.__make_output_iterator(), __ctx}; __format_range(__range, __c, __specs); return __formatter::__write_string_no_precision(__buffer.__view(), __ctx.out(), __specs); } template typename _FormatContext::iterator _LIBCPP_HIDE_FROM_ABI __format_range(_Rp&& __range, _FormatContext& __ctx, __format_spec::__parsed_specifications<_CharT> __specs) const { if constexpr (same_as<_Tp, _CharT>) { switch (__specs.__std_.__type_) { case __format_spec::__type::__string: case __format_spec::__type::__debug: return __format_as_string(__range, __ctx, __specs.__std_.__type_ == __format_spec::__type::__debug); default: return __format_as_sequence(__range, __ctx); } } else return __format_as_sequence(__range, __ctx); } template _LIBCPP_HIDE_FROM_ABI typename _FormatContext::iterator __format_as_string(_Rp&& __range, _FormatContext& __ctx, bool __debug_format) const { // When the range is contiguous use a basic_string_view instead to avoid a // copy of the underlying data. The basic_string_view formatter // specialization is the "basic" string formatter in libc++. if constexpr (ranges::contiguous_range<_Rp> && std::ranges::sized_range<_Rp>) { std::formatter, _CharT> __formatter; if (__debug_format) __formatter.set_debug_format(); return __formatter.format( basic_string_view<_CharT>{ ranges::data(__range), ranges::size(__range), }, __ctx); } else { std::formatter, _CharT> __formatter; if (__debug_format) __formatter.set_debug_format(); return __formatter.format(basic_string<_CharT>{from_range, __range}, __ctx); } } template _LIBCPP_HIDE_FROM_ABI typename _FormatContext::iterator __format_as_sequence(_Rp&& __range, _FormatContext& __ctx) const { __ctx.advance_to(ranges::copy(__opening_bracket_, __ctx.out()).out); bool __use_separator = false; for (auto&& __e : __range) { if (__use_separator) __ctx.advance_to(ranges::copy(__separator_, __ctx.out()).out); else __use_separator = true; __ctx.advance_to(__underlying_.format(__e, __ctx)); } return ranges::copy(__closing_bracket_, __ctx.out()).out; } __format_spec::__parser<_CharT> __parser_{.__alignment_ = __format_spec::__alignment::__left}; private: template _LIBCPP_HIDE_FROM_ABI constexpr void __parse_type(_Iterator& __begin, _Iterator __end) { switch (*__begin) { case _CharT('m'): if constexpr (__fmt_pair_like<_Tp>) { set_brackets(_LIBCPP_STATICALLY_WIDEN(_CharT, "{"), _LIBCPP_STATICALLY_WIDEN(_CharT, "}")); set_separator(_LIBCPP_STATICALLY_WIDEN(_CharT, ", ")); ++__begin; } else std::__throw_format_error("Type m requires a pair or a tuple with two elements"); break; case _CharT('s'): if constexpr (same_as<_Tp, _CharT>) { __parser_.__type_ = __format_spec::__type::__string; ++__begin; } else std::__throw_format_error("Type s requires character type as formatting argument"); break; case _CharT('?'): ++__begin; if (__begin == __end || *__begin != _CharT('s')) std::__throw_format_error("The format specifier should consume the input or end with a '}'"); if constexpr (same_as<_Tp, _CharT>) { __parser_.__type_ = __format_spec::__type::__debug; ++__begin; } else std::__throw_format_error("Type ?s requires character type as formatting argument"); } } template _LIBCPP_HIDE_FROM_ABI constexpr typename _ParseContext::iterator __parse_empty_range_underlying_spec(_ParseContext& __ctx, typename _ParseContext::iterator __begin) { __ctx.advance_to(__begin); [[maybe_unused]] typename _ParseContext::iterator __result = __underlying_.parse(__ctx); _LIBCPP_ASSERT_INTERNAL(__result == __begin, "the underlying's parse function should not advance the input beyond the end of the input"); return __begin; } formatter<_Tp, _CharT> __underlying_; basic_string_view<_CharT> __separator_ = _LIBCPP_STATICALLY_WIDEN(_CharT, ", "); basic_string_view<_CharT> __opening_bracket_ = _LIBCPP_STATICALLY_WIDEN(_CharT, "["); basic_string_view<_CharT> __closing_bracket_ = _LIBCPP_STATICALLY_WIDEN(_CharT, "]"); }; #endif //_LIBCPP_STD_VER >= 23 _LIBCPP_END_NAMESPACE_STD #endif // _LIBCPP___FORMAT_RANGE_FORMATTER_H