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llvm / llvm-project / d5ce68afdf65fd8906d9570c0a71d3557de70838 / . / libcxx / include / __format / formatter_output.h
blob: 85f45779ff33e0563ece69459b50638d3a8eab4c [file] [log] [blame]
// -*- 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_FORMATTER_OUTPUT_H
#define _LIBCPP___FORMAT_FORMATTER_OUTPUT_H
#include <__algorithm/ranges_copy.h>
#include <__algorithm/ranges_fill_n.h>
#include <__algorithm/ranges_for_each.h>
#include <__algorithm/ranges_transform.h>
#include <__bit/countl.h>
#include <__charconv/to_chars_integral.h>
#include <__charconv/to_chars_result.h>
#include <__chrono/statically_widen.h>
#include <__concepts/same_as.h>
#include <__config>
#include <__format/buffer.h>
#include <__format/concepts.h>
#include <__format/escaped_output_table.h>
#include <__format/formatter.h>
#include <__format/parser_std_format_spec.h>
#include <__format/unicode.h>
#include <__iterator/back_insert_iterator.h>
#include <__iterator/concepts.h>
#include <__iterator/iterator_traits.h> // iter_value_t
#include <__system_error/errc.h>
#include <__type_traits/make_unsigned.h>
#include <__utility/move.h>
#include <__utility/unreachable.h>
#include <cstddef>
#include <string>
#include <string_view>
#if !defined(_LIBCPP_HAS_NO_PRAGMA_SYSTEM_HEADER)
# pragma GCC system_header
#endif
_LIBCPP_BEGIN_NAMESPACE_STD
#if _LIBCPP_STD_VER >= 20
namespace __formatter {
_LIBCPP_HIDE_FROM_ABI constexpr char __hex_to_upper(char __c) {
switch (__c) {
case 'a':
return 'A';
case 'b':
return 'B';
case 'c':
return 'C';
case 'd':
return 'D';
case 'e':
return 'E';
case 'f':
return 'F';
}
return __c;
}
struct _LIBCPP_EXPORTED_FROM_ABI __padding_size_result {
size_t __before_;
size_t __after_;
};
_LIBCPP_HIDE_FROM_ABI constexpr __padding_size_result
__padding_size(size_t __size, size_t __width, __format_spec::__alignment __align) {
_LIBCPP_ASSERT(__width > __size, "don't call this function when no padding is required");
_LIBCPP_ASSERT(
__align != __format_spec::__alignment::__zero_padding, "the caller should have handled the zero-padding");
size_t __fill = __width - __size;
switch (__align) {
case __format_spec::__alignment::__zero_padding:
__libcpp_unreachable();
case __format_spec::__alignment::__left:
return {0, __fill};
case __format_spec::__alignment::__center: {
// The extra padding is divided per [format.string.std]/3
// __before = floor(__fill, 2);
// __after = ceil(__fill, 2);
size_t __before = __fill / 2;
size_t __after = __fill - __before;
return {__before, __after};
}
case __format_spec::__alignment::__default:
case __format_spec::__alignment::__right:
return {__fill, 0};
}
__libcpp_unreachable();
}
/// Copy wrapper.
///
/// This uses a "mass output function" of __format::__output_buffer when possible.
template <__fmt_char_type _CharT, __fmt_char_type _OutCharT = _CharT>
_LIBCPP_HIDE_FROM_ABI auto __copy(basic_string_view<_CharT> __str, output_iterator<const _OutCharT&> auto __out_it)
-> decltype(__out_it) {
if constexpr (_VSTD::same_as<decltype(__out_it), _VSTD::back_insert_iterator<__format::__output_buffer<_OutCharT>>>) {
__out_it.__get_container()->__copy(__str);
return __out_it;
} else if constexpr (_VSTD::same_as<decltype(__out_it),
typename __format::__retarget_buffer<_OutCharT>::__iterator>) {
__out_it.__buffer_->__copy(__str);
return __out_it;
} else {
return std::ranges::copy(__str, _VSTD::move(__out_it)).out;
}
}
template <__fmt_char_type _CharT, __fmt_char_type _OutCharT = _CharT>
_LIBCPP_HIDE_FROM_ABI auto
__copy(const _CharT* __first, const _CharT* __last, output_iterator<const _OutCharT&> auto __out_it)
-> decltype(__out_it) {
return __formatter::__copy(basic_string_view{__first, __last}, _VSTD::move(__out_it));
}
template <__fmt_char_type _CharT, __fmt_char_type _OutCharT = _CharT>
_LIBCPP_HIDE_FROM_ABI auto __copy(const _CharT* __first, size_t __n, output_iterator<const _OutCharT&> auto __out_it)
-> decltype(__out_it) {
return __formatter::__copy(basic_string_view{__first, __n}, _VSTD::move(__out_it));
}
/// Transform wrapper.
///
/// This uses a "mass output function" of __format::__output_buffer when possible.
template <__fmt_char_type _CharT, __fmt_char_type _OutCharT = _CharT, class _UnaryOperation>
_LIBCPP_HIDE_FROM_ABI auto
__transform(const _CharT* __first,
const _CharT* __last,
output_iterator<const _OutCharT&> auto __out_it,
_UnaryOperation __operation) -> decltype(__out_it) {
if constexpr (_VSTD::same_as<decltype(__out_it), _VSTD::back_insert_iterator<__format::__output_buffer<_OutCharT>>>) {
__out_it.__get_container()->__transform(__first, __last, _VSTD::move(__operation));
return __out_it;
} else if constexpr (_VSTD::same_as<decltype(__out_it),
typename __format::__retarget_buffer<_OutCharT>::__iterator>) {
__out_it.__buffer_->__transform(__first, __last, _VSTD::move(__operation));
return __out_it;
} else {
return std::ranges::transform(__first, __last, _VSTD::move(__out_it), __operation).out;
}
}
/// Fill wrapper.
///
/// This uses a "mass output function" of __format::__output_buffer when possible.
template <__fmt_char_type _CharT, output_iterator<const _CharT&> _OutIt>
_LIBCPP_HIDE_FROM_ABI _OutIt __fill(_OutIt __out_it, size_t __n, _CharT __value) {
if constexpr (_VSTD::same_as<decltype(__out_it), _VSTD::back_insert_iterator<__format::__output_buffer<_CharT>>>) {
__out_it.__get_container()->__fill(__n, __value);
return __out_it;
} else if constexpr (_VSTD::same_as<decltype(__out_it), typename __format::__retarget_buffer<_CharT>::__iterator>) {
__out_it.__buffer_->__fill(__n, __value);
return __out_it;
} else {
return std::ranges::fill_n(_VSTD::move(__out_it), __n, __value);
}
}
# ifndef _LIBCPP_HAS_NO_UNICODE
template <__fmt_char_type _CharT, output_iterator<const _CharT&> _OutIt>
requires(same_as<_CharT, char>)
_LIBCPP_HIDE_FROM_ABI _OutIt __fill(_OutIt __out_it, size_t __n, __format_spec::__code_point<_CharT> __value) {
std::size_t __bytes = std::countl_one(static_cast<unsigned char>(__value.__data[0]));
if (__bytes == 0)
return __formatter::__fill(std::move(__out_it), __n, __value.__data[0]);
for (size_t __i = 0; __i < __n; ++__i)
__out_it = __formatter::__copy(
std::addressof(__value.__data[0]), std::addressof(__value.__data[0]) + __bytes, std::move(__out_it));
return __out_it;
}
# ifndef _LIBCPP_HAS_NO_WIDE_CHARACTERS
template <__fmt_char_type _CharT, output_iterator<const _CharT&> _OutIt>
requires(same_as<_CharT, wchar_t> && sizeof(wchar_t) == 2)
_LIBCPP_HIDE_FROM_ABI _OutIt __fill(_OutIt __out_it, size_t __n, __format_spec::__code_point<_CharT> __value) {
if (!__unicode::__is_high_surrogate(__value.__data[0]))
return __formatter::__fill(std::move(__out_it), __n, __value.__data[0]);
for (size_t __i = 0; __i < __n; ++__i)
__out_it = __formatter::__copy(
std::addressof(__value.__data[0]), std::addressof(__value.__data[0]) + 2, std::move(__out_it));
return __out_it;
}
template <__fmt_char_type _CharT, output_iterator<const _CharT&> _OutIt>
requires(same_as<_CharT, wchar_t> && sizeof(wchar_t) == 4)
_LIBCPP_HIDE_FROM_ABI _OutIt __fill(_OutIt __out_it, size_t __n, __format_spec::__code_point<_CharT> __value) {
return __formatter::__fill(std::move(__out_it), __n, __value.__data[0]);
}
# endif // _LIBCPP_HAS_NO_WIDE_CHARACTERS
# else // _LIBCPP_HAS_NO_UNICODE
template <__fmt_char_type _CharT, output_iterator<const _CharT&> _OutIt>
_LIBCPP_HIDE_FROM_ABI _OutIt __fill(_OutIt __out_it, size_t __n, __format_spec::__code_point<_CharT> __value) {
return __formatter::__fill(std::move(__out_it), __n, __value.__data[0]);
}
# endif // _LIBCPP_HAS_NO_UNICODE
template <class _OutIt, class _CharT>
_LIBCPP_HIDE_FROM_ABI _OutIt __write_using_decimal_separators(_OutIt __out_it, const char* __begin, const char* __first,
const char* __last, string&& __grouping, _CharT __sep,
__format_spec::__parsed_specifications<_CharT> __specs) {
int __size = (__first - __begin) + // [sign][prefix]
(__last - __first) + // data
(__grouping.size() - 1); // number of separator characters
__padding_size_result __padding = {0, 0};
if (__specs.__alignment_ == __format_spec::__alignment::__zero_padding) {
// Write [sign][prefix].
__out_it = __formatter::__copy(__begin, __first, _VSTD::move(__out_it));
if (__specs.__width_ > __size) {
// Write zero padding.
__padding.__before_ = __specs.__width_ - __size;
__out_it = __formatter::__fill(_VSTD::move(__out_it), __specs.__width_ - __size, _CharT('0'));
}
} else {
if (__specs.__width_ > __size) {
// Determine padding and write padding.
__padding = __formatter::__padding_size(__size, __specs.__width_, __specs.__alignment_);
__out_it = __formatter::__fill(_VSTD::move(__out_it), __padding.__before_, __specs.__fill_);
}
// Write [sign][prefix].
__out_it = __formatter::__copy(__begin, __first, _VSTD::move(__out_it));
}
auto __r = __grouping.rbegin();
auto __e = __grouping.rend() - 1;
_LIBCPP_ASSERT(__r != __e, "The slow grouping formatting is used while "
"there will be no separators written.");
// The output is divided in small groups of numbers to write:
// - A group before the first separator.
// - A separator and a group, repeated for the number of separators.
// - A group after the last separator.
// This loop achieves that process by testing the termination condition
// midway in the loop.
//
// TODO FMT This loop evaluates the loop invariant `__parser.__type !=
// _Flags::_Type::__hexadecimal_upper_case` for every iteration. (This test
// happens in the __write call.) Benchmark whether making two loops and
// hoisting the invariant is worth the effort.
while (true) {
if (__specs.__std_.__type_ == __format_spec::__type::__hexadecimal_upper_case) {
__last = __first + *__r;
__out_it = __formatter::__transform(__first, __last, _VSTD::move(__out_it), __hex_to_upper);
__first = __last;
} else {
__out_it = __formatter::__copy(__first, *__r, _VSTD::move(__out_it));
__first += *__r;
}
if (__r == __e)
break;
++__r;
*__out_it++ = __sep;
}
return __formatter::__fill(_VSTD::move(__out_it), __padding.__after_, __specs.__fill_);
}
/// Writes the input to the output with the required padding.
///
/// Since the output column width is specified the function can be used for
/// ASCII and Unicode output.
///
/// \pre \a __size <= \a __width. Using this function when this pre-condition
/// doesn't hold incurs an unwanted overhead.
///
/// \param __str The string to write.
/// \param __out_it The output iterator to write to.
/// \param __specs The parsed formatting specifications.
/// \param __size The (estimated) output column width. When the elements
/// to be written are ASCII the following condition holds
/// \a __size == \a __last - \a __first.
///
/// \returns An iterator pointing beyond the last element written.
///
/// \note The type of the elements in range [\a __first, \a __last) can differ
/// from the type of \a __specs. Integer output uses \c std::to_chars for its
/// conversion, which means the [\a __first, \a __last) always contains elements
/// of the type \c char.
template <class _CharT, class _ParserCharT>
_LIBCPP_HIDE_FROM_ABI auto
__write(basic_string_view<_CharT> __str,
output_iterator<const _CharT&> auto __out_it,
__format_spec::__parsed_specifications<_ParserCharT> __specs,
ptrdiff_t __size) -> decltype(__out_it) {
if (__size >= __specs.__width_)
return __formatter::__copy(__str, _VSTD::move(__out_it));
__padding_size_result __padding = __formatter::__padding_size(__size, __specs.__width_, __specs.__std_.__alignment_);
__out_it = __formatter::__fill(_VSTD::move(__out_it), __padding.__before_, __specs.__fill_);
__out_it = __formatter::__copy(__str, _VSTD::move(__out_it));
return __formatter::__fill(_VSTD::move(__out_it), __padding.__after_, __specs.__fill_);
}
template <contiguous_iterator _Iterator, class _ParserCharT>
_LIBCPP_HIDE_FROM_ABI auto
__write(_Iterator __first,
_Iterator __last,
output_iterator<const iter_value_t<_Iterator>&> auto __out_it,
__format_spec::__parsed_specifications<_ParserCharT> __specs,
ptrdiff_t __size) -> decltype(__out_it) {
_LIBCPP_ASSERT(__first <= __last, "Not a valid range");
return __formatter::__write(basic_string_view{__first, __last}, _VSTD::move(__out_it), __specs, __size);
}
/// \overload
///
/// Calls the function above where \a __size = \a __last - \a __first.
template <contiguous_iterator _Iterator, class _ParserCharT>
_LIBCPP_HIDE_FROM_ABI auto
__write(_Iterator __first,
_Iterator __last,
output_iterator<const iter_value_t<_Iterator>&> auto __out_it,
__format_spec::__parsed_specifications<_ParserCharT> __specs) -> decltype(__out_it) {
_LIBCPP_ASSERT(__first <= __last, "Not a valid range");
return __formatter::__write(__first, __last, _VSTD::move(__out_it), __specs, __last - __first);
}
template <class _CharT, class _ParserCharT, class _UnaryOperation>
_LIBCPP_HIDE_FROM_ABI auto __write_transformed(const _CharT* __first, const _CharT* __last,
output_iterator<const _CharT&> auto __out_it,
__format_spec::__parsed_specifications<_ParserCharT> __specs,
_UnaryOperation __op) -> decltype(__out_it) {
_LIBCPP_ASSERT(__first <= __last, "Not a valid range");
ptrdiff_t __size = __last - __first;
if (__size >= __specs.__width_)
return __formatter::__transform(__first, __last, _VSTD::move(__out_it), __op);
__padding_size_result __padding = __formatter::__padding_size(__size, __specs.__width_, __specs.__alignment_);
__out_it = __formatter::__fill(_VSTD::move(__out_it), __padding.__before_, __specs.__fill_);
__out_it = __formatter::__transform(__first, __last, _VSTD::move(__out_it), __op);
return __formatter::__fill(_VSTD::move(__out_it), __padding.__after_, __specs.__fill_);
}
/// Writes additional zero's for the precision before the exponent.
/// This is used when the precision requested in the format string is larger
/// than the maximum precision of the floating-point type. These precision
/// digits are always 0.
///
/// \param __exponent The location of the exponent character.
/// \param __num_trailing_zeros The number of 0's to write before the exponent
/// character.
template <class _CharT, class _ParserCharT>
_LIBCPP_HIDE_FROM_ABI auto __write_using_trailing_zeros(
const _CharT* __first,
const _CharT* __last,
output_iterator<const _CharT&> auto __out_it,
__format_spec::__parsed_specifications<_ParserCharT> __specs,
size_t __size,
const _CharT* __exponent,
size_t __num_trailing_zeros) -> decltype(__out_it) {
_LIBCPP_ASSERT(__first <= __last, "Not a valid range");
_LIBCPP_ASSERT(__num_trailing_zeros > 0, "The overload not writing trailing zeros should have been used");
__padding_size_result __padding =
__formatter::__padding_size(__size + __num_trailing_zeros, __specs.__width_, __specs.__alignment_);
__out_it = __formatter::__fill(_VSTD::move(__out_it), __padding.__before_, __specs.__fill_);
__out_it = __formatter::__copy(__first, __exponent, _VSTD::move(__out_it));
__out_it = __formatter::__fill(_VSTD::move(__out_it), __num_trailing_zeros, _CharT('0'));
__out_it = __formatter::__copy(__exponent, __last, _VSTD::move(__out_it));
return __formatter::__fill(_VSTD::move(__out_it), __padding.__after_, __specs.__fill_);
}
/// Writes a string using format's width estimation algorithm.
///
/// \pre !__specs.__has_precision()
///
/// \note When \c _LIBCPP_HAS_NO_UNICODE is defined the function assumes the
/// input is ASCII.
template <class _CharT>
_LIBCPP_HIDE_FROM_ABI auto __write_string_no_precision(
basic_string_view<_CharT> __str,
output_iterator<const _CharT&> auto __out_it,
__format_spec::__parsed_specifications<_CharT> __specs) -> decltype(__out_it) {
_LIBCPP_ASSERT(!__specs.__has_precision(), "use __write_string");
// No padding -> copy the string
if (!__specs.__has_width())
return __formatter::__copy(__str, _VSTD::move(__out_it));
// Note when the estimated width is larger than size there's no padding. So
// there's no reason to get the real size when the estimate is larger than or
// equal to the minimum field width.
size_t __size =
__format_spec::__estimate_column_width(__str, __specs.__width_, __format_spec::__column_width_rounding::__up)
.__width_;
return __formatter::__write(__str, _VSTD::move(__out_it), __specs, __size);
}
template <class _CharT>
_LIBCPP_HIDE_FROM_ABI int __truncate(basic_string_view<_CharT>& __str, int __precision) {
__format_spec::__column_width_result __result =
__format_spec::__estimate_column_width(__str, __precision, __format_spec::__column_width_rounding::__down);
__str = basic_string_view<_CharT>{__str.begin(), __result.__last_};
return __result.__width_;
}
/// Writes a string using format's width estimation algorithm.
///
/// \note When \c _LIBCPP_HAS_NO_UNICODE is defined the function assumes the
/// input is ASCII.
template <class _CharT>
_LIBCPP_HIDE_FROM_ABI auto __write_string(
basic_string_view<_CharT> __str,
output_iterator<const _CharT&> auto __out_it,
__format_spec::__parsed_specifications<_CharT> __specs) -> decltype(__out_it) {
if (!__specs.__has_precision())
return __formatter::__write_string_no_precision(__str, _VSTD::move(__out_it), __specs);
int __size = __formatter::__truncate(__str, __specs.__precision_);
return __formatter::__write(__str.begin(), __str.end(), _VSTD::move(__out_it), __specs, __size);
}
# if _LIBCPP_STD_VER >= 23
struct __nul_terminator {};
template <class _CharT>
_LIBCPP_HIDE_FROM_ABI bool operator==(const _CharT* __cstr, __nul_terminator) {
return *__cstr == _CharT('\0');
}
template <class _CharT>
_LIBCPP_HIDE_FROM_ABI void
__write_escaped_code_unit(basic_string<_CharT>& __str, char32_t __value, const _CharT* __prefix) {
back_insert_iterator __out_it{__str};
std::ranges::copy(__prefix, __nul_terminator{}, __out_it);
char __buffer[8];
to_chars_result __r = std::to_chars(std::begin(__buffer), std::end(__buffer), __value, 16);
_LIBCPP_ASSERT(__r.ec == errc(0), "Internal buffer too small");
std::ranges::copy(std::begin(__buffer), __r.ptr, __out_it);
__str += _CharT('}');
}
// [format.string.escaped]/2.2.1.2
// ...
// then the sequence \u{hex-digit-sequence} is appended to E, where
// hex-digit-sequence is the shortest hexadecimal representation of C using
// lower-case hexadecimal digits.
template <class _CharT>
_LIBCPP_HIDE_FROM_ABI void __write_well_formed_escaped_code_unit(basic_string<_CharT>& __str, char32_t __value) {
__formatter::__write_escaped_code_unit(__str, __value, _LIBCPP_STATICALLY_WIDEN(_CharT, "\\u{"));
}
// [format.string.escaped]/2.2.3
// Otherwise (X is a sequence of ill-formed code units), each code unit U is
// appended to E in order as the sequence \x{hex-digit-sequence}, where
// hex-digit-sequence is the shortest hexadecimal representation of U using
// lower-case hexadecimal digits.
template <class _CharT>
_LIBCPP_HIDE_FROM_ABI void __write_escape_ill_formed_code_unit(basic_string<_CharT>& __str, char32_t __value) {
__formatter::__write_escaped_code_unit(__str, __value, _LIBCPP_STATICALLY_WIDEN(_CharT, "\\x{"));
}
template <class _CharT>
[[nodiscard]] _LIBCPP_HIDE_FROM_ABI bool __is_escaped_sequence_written(basic_string<_CharT>& __str, char32_t __value) {
# ifdef _LIBCPP_HAS_NO_UNICODE
// For ASCII assume everything above 127 is printable.
if (__value > 127)
return false;
# endif
if (!__escaped_output_table::__needs_escape(__value))
return false;
__formatter::__write_well_formed_escaped_code_unit(__str, __value);
return true;
}
template <class _CharT>
[[nodiscard]] _LIBCPP_HIDE_FROM_ABI constexpr char32_t __to_char32(_CharT __value) {
return static_cast<make_unsigned_t<_CharT>>(__value);
}
enum class _LIBCPP_ENUM_VIS __escape_quotation_mark { __apostrophe, __double_quote };
// [format.string.escaped]/2
template <class _CharT>
[[nodiscard]] _LIBCPP_HIDE_FROM_ABI bool
__is_escaped_sequence_written(basic_string<_CharT>& __str, char32_t __value, __escape_quotation_mark __mark) {
// 2.2.1.1 - Mapped character in [tab:format.escape.sequences]
switch (__value) {
case _CharT('\t'):
__str += _LIBCPP_STATICALLY_WIDEN(_CharT, "\\t");
return true;
case _CharT('\n'):
__str += _LIBCPP_STATICALLY_WIDEN(_CharT, "\\n");
return true;
case _CharT('\r'):
__str += _LIBCPP_STATICALLY_WIDEN(_CharT, "\\r");
return true;
case _CharT('\''):
if (__mark == __escape_quotation_mark::__apostrophe)
__str += _LIBCPP_STATICALLY_WIDEN(_CharT, R"(\')");
else
__str += __value;
return true;
case _CharT('"'):
if (__mark == __escape_quotation_mark::__double_quote)
__str += _LIBCPP_STATICALLY_WIDEN(_CharT, R"(\")");
else
__str += __value;
return true;
case _CharT('\\'):
__str += _LIBCPP_STATICALLY_WIDEN(_CharT, R"(\\)");
return true;
// 2.2.1.2 - Space
case _CharT(' '):
__str += __value;
return true;
}
// 2.2.2
// Otherwise, if X is a shift sequence, the effect on E and further
// decoding of S is unspecified.
// For now shift sequences are ignored and treated as Unicode. Other parts
// of the format library do the same. It's unknown how ostream treats them.
// TODO FMT determine what to do with shift sequences.
// 2.2.1.2.1 and 2.2.1.2.2 - Escape
return __formatter::__is_escaped_sequence_written(__str, __formatter::__to_char32(__value));
}
template <class _CharT>
_LIBCPP_HIDE_FROM_ABI void
__escape(basic_string<_CharT>& __str, basic_string_view<_CharT> __values, __escape_quotation_mark __mark) {
__unicode::__code_point_view<_CharT> __view{__values.begin(), __values.end()};
while (!__view.__at_end()) {
auto __first = __view.__position();
typename __unicode::__consume_result __result = __view.__consume();
if (__result.__status == __unicode::__consume_result::__ok) {
if (!__formatter::__is_escaped_sequence_written(__str, __result.__code_point, __mark))
// 2.2.1.3 - Add the character
ranges::copy(__first, __view.__position(), std::back_insert_iterator(__str));
} else {
// 2.2.3 sequence of ill-formed code units
ranges::for_each(__first, __view.__position(), [&](_CharT __value) {
__formatter::__write_escape_ill_formed_code_unit(__str, __formatter::__to_char32(__value));
});
}
}
}
template <class _CharT>
_LIBCPP_HIDE_FROM_ABI auto
__format_escaped_char(_CharT __value,
output_iterator<const _CharT&> auto __out_it,
__format_spec::__parsed_specifications<_CharT> __specs) -> decltype(__out_it) {
basic_string<_CharT> __str;
__str += _CharT('\'');
__formatter::__escape(__str, basic_string_view{std::addressof(__value), 1}, __escape_quotation_mark::__apostrophe);
__str += _CharT('\'');
return __formatter::__write(__str.data(), __str.data() + __str.size(), _VSTD::move(__out_it), __specs, __str.size());
}
template <class _CharT>
_LIBCPP_HIDE_FROM_ABI auto
__format_escaped_string(basic_string_view<_CharT> __values,
output_iterator<const _CharT&> auto __out_it,
__format_spec::__parsed_specifications<_CharT> __specs) -> decltype(__out_it) {
basic_string<_CharT> __str;
__str += _CharT('"');
__formatter::__escape(__str, __values, __escape_quotation_mark::__double_quote);
__str += _CharT('"');
return __formatter::__write_string(basic_string_view{__str}, _VSTD::move(__out_it), __specs);
}
# endif // _LIBCPP_STD_VER >= 23
} // namespace __formatter
#endif //_LIBCPP_STD_VER >= 20
_LIBCPP_END_NAMESPACE_STD
#endif // _LIBCPP___FORMAT_FORMATTER_OUTPUT_H