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|
#pragma once
#include <cstring>
#include <cstdio>
#include <limits>
#include <algorithm>
#include <iterator>
#include <concepts>
#include <bit>
#include <pcg-random/pcg_random.hpp>
#include <Common/StackTrace.h>
#include <Common/formatIPv6.h>
#include <Common/DateLUT.h>
#include <Common/LocalDate.h>
#include <Common/LocalDateTime.h>
#include <Common/TransformEndianness.hpp>
#include <base/find_symbols.h>
#include <base/StringRef.h>
#include <base/DecomposedFloat.h>
#include <base/EnumReflection.h>
#include <Core/DecimalFunctions.h>
#include <Core/Types.h>
#include <Core/UUID.h>
#include <base/IPv4andIPv6.h>
#include <Common/Exception.h>
#include <Common/StringUtils/StringUtils.h>
#include <Common/NaNUtils.h>
#include <IO/CompressionMethod.h>
#include <IO/WriteBuffer.h>
#include <IO/WriteIntText.h>
#include <IO/VarInt.h>
#include <IO/DoubleConverter.h>
#include <IO/WriteBufferFromString.h>
#ifdef __clang__
#pragma clang diagnostic push
#pragma clang diagnostic ignored "-Wunused-parameter"
#pragma clang diagnostic ignored "-Wsign-compare"
#endif
#include <dragonbox/dragonbox_to_chars.h>
#ifdef __clang__
#pragma clang diagnostic pop
#endif
#include <Formats/FormatSettings.h>
namespace DB
{
namespace ErrorCodes
{
extern const int CANNOT_PRINT_FLOAT_OR_DOUBLE_NUMBER;
}
/// Helper functions for formatted and binary output.
inline void writeChar(char x, WriteBuffer & buf)
{
buf.nextIfAtEnd();
*buf.position() = x;
++buf.position();
}
/// Write the same character n times.
inline void writeChar(char c, size_t n, WriteBuffer & buf)
{
while (n)
{
buf.nextIfAtEnd();
size_t count = std::min(n, buf.available());
memset(buf.position(), c, count);
n -= count;
buf.position() += count;
}
}
/// Write POD-type in native format. It's recommended to use only with packed (dense) data types.
template <typename T>
inline void writePODBinary(const T & x, WriteBuffer & buf)
{
buf.write(reinterpret_cast<const char *>(&x), sizeof(x)); /// NOLINT
}
inline void writeUUIDBinary(const UUID & x, WriteBuffer & buf)
{
const auto & uuid = x.toUnderType();
writePODBinary(uuid.items[0], buf);
writePODBinary(uuid.items[1], buf);
}
template <typename T>
inline void writeIntBinary(const T & x, WriteBuffer & buf)
{
writePODBinary(x, buf);
}
template <typename T>
inline void writeFloatBinary(const T & x, WriteBuffer & buf)
{
writePODBinary(x, buf);
}
inline void writeStringBinary(const std::string & s, WriteBuffer & buf)
{
writeVarUInt(s.size(), buf);
buf.write(s.data(), s.size());
}
/// For historical reasons we store IPv6 as a String
inline void writeIPv6Binary(const IPv6 & ip, WriteBuffer & buf)
{
writeVarUInt(IPV6_BINARY_LENGTH, buf);
buf.write(reinterpret_cast<const char *>(&ip.toUnderType()), IPV6_BINARY_LENGTH);
}
inline void writeStringBinary(StringRef s, WriteBuffer & buf)
{
writeVarUInt(s.size, buf);
buf.write(s.data, s.size);
}
inline void writeStringBinary(const char * s, WriteBuffer & buf)
{
writeStringBinary(StringRef{s}, buf);
}
inline void writeStringBinary(std::string_view s, WriteBuffer & buf)
{
writeStringBinary(StringRef{s}, buf);
}
template <typename T>
void writeVectorBinary(const std::vector<T> & v, WriteBuffer & buf)
{
writeVarUInt(v.size(), buf);
for (typename std::vector<T>::const_iterator it = v.begin(); it != v.end(); ++it)
writeBinary(*it, buf);
}
inline void writeBoolText(bool x, WriteBuffer & buf)
{
writeChar(x ? '1' : '0', buf);
}
template <typename T>
inline size_t writeFloatTextFastPath(T x, char * buffer)
{
Int64 result = 0;
if constexpr (std::is_same_v<T, double>)
{
/// The library Ryu has low performance on integers.
/// This workaround improves performance 6..10 times.
if (DecomposedFloat64(x).isIntegerInRepresentableRange())
result = itoa(Int64(x), buffer) - buffer;
else
result = jkj::dragonbox::to_chars_n(x, buffer) - buffer;
}
else
{
if (DecomposedFloat32(x).isIntegerInRepresentableRange())
result = itoa(Int32(x), buffer) - buffer;
else
result = jkj::dragonbox::to_chars_n(x, buffer) - buffer;
}
if (result <= 0)
throw Exception(ErrorCodes::CANNOT_PRINT_FLOAT_OR_DOUBLE_NUMBER, "Cannot print floating point number");
return result;
}
template <typename T>
inline void writeFloatText(T x, WriteBuffer & buf)
{
static_assert(std::is_same_v<T, double> || std::is_same_v<T, float>, "Argument for writeFloatText must be float or double");
using Converter = DoubleConverter<false>;
if (likely(buf.available() >= Converter::MAX_REPRESENTATION_LENGTH))
{
buf.position() += writeFloatTextFastPath(x, buf.position());
return;
}
Converter::BufferType buffer;
size_t result = writeFloatTextFastPath(x, buffer);
buf.write(buffer, result);
}
inline void writeString(const char * data, size_t size, WriteBuffer & buf)
{
buf.write(data, size);
}
// Otherwise StringRef and string_view overloads are ambiguous when passing string literal. Prefer std::string_view
void writeString(std::same_as<StringRef> auto ref, WriteBuffer & buf)
{
writeString(ref.data, ref.size, buf);
}
inline void writeString(std::string_view ref, WriteBuffer & buf)
{
writeString(ref.data(), ref.size(), buf);
}
/** Writes a C-string without creating a temporary object. If the string is a literal, then `strlen` is executed at the compilation stage.
* Use when the string is a literal.
*/
#define writeCString(s, buf) \
(buf).write((s), strlen(s))
/** Writes a string for use in the JSON format:
* - the string is written in double quotes
* - slash character '/' is escaped for compatibility with JavaScript
* - bytes from the range 0x00-0x1F except `\b', '\f', '\n', '\r', '\t' are escaped as \u00XX
* - code points U+2028 and U+2029 (byte sequences in UTF-8: e2 80 a8, e2 80 a9) are escaped as \u2028 and \u2029
* - it is assumed that string is in UTF-8, the invalid UTF-8 is not processed
* - all other non-ASCII characters remain as is
*/
inline void writeJSONString(const char * begin, const char * end, WriteBuffer & buf, const FormatSettings & settings)
{
writeChar('"', buf);
for (const char * it = begin; it != end; ++it)
{
switch (*it)
{
case '\b':
writeChar('\\', buf);
writeChar('b', buf);
break;
case '\f':
writeChar('\\', buf);
writeChar('f', buf);
break;
case '\n':
writeChar('\\', buf);
writeChar('n', buf);
break;
case '\r':
writeChar('\\', buf);
writeChar('r', buf);
break;
case '\t':
writeChar('\\', buf);
writeChar('t', buf);
break;
case '\\':
writeChar('\\', buf);
writeChar('\\', buf);
break;
case '/':
if (settings.json.escape_forward_slashes)
writeChar('\\', buf);
writeChar('/', buf);
break;
case '"':
writeChar('\\', buf);
writeChar('"', buf);
break;
default:
UInt8 c = *it;
if (c <= 0x1F)
{
/// Escaping of ASCII control characters.
UInt8 higher_half = c >> 4;
UInt8 lower_half = c & 0xF;
writeCString("\\u00", buf);
writeChar('0' + higher_half, buf);
if (lower_half <= 9)
writeChar('0' + lower_half, buf);
else
writeChar('A' + lower_half - 10, buf);
}
else if (end - it >= 3 && it[0] == '\xE2' && it[1] == '\x80' && (it[2] == '\xA8' || it[2] == '\xA9'))
{
/// This is for compatibility with JavaScript, because unescaped line separators are prohibited in string literals,
/// and these code points are alternative line separators.
if (it[2] == '\xA8')
writeCString("\\u2028", buf);
if (it[2] == '\xA9')
writeCString("\\u2029", buf);
/// Byte sequence is 3 bytes long. We have additional two bytes to skip.
it += 2;
}
else
writeChar(*it, buf);
}
}
writeChar('"', buf);
}
/** Will escape quote_character and a list of special characters('\b', '\f', '\n', '\r', '\t', '\0', '\\').
* - when escape_quote_with_quote is true, use backslash to escape list of special characters,
* and use quote_character to escape quote_character. such as: 'hello''world'
* otherwise use backslash to escape list of special characters and quote_character
* - when escape_backslash_with_backslash is true, backslash is escaped with another backslash
*/
template <char quote_character, bool escape_quote_with_quote = false, bool escape_backslash_with_backslash = true>
void writeAnyEscapedString(const char * begin, const char * end, WriteBuffer & buf)
{
const char * pos = begin;
while (true)
{
/// On purpose we will escape more characters than minimally necessary.
const char * next_pos = find_first_symbols<'\b', '\f', '\n', '\r', '\t', '\0', '\\', quote_character>(pos, end);
if (next_pos == end)
{
buf.write(pos, next_pos - pos);
break;
}
else
{
buf.write(pos, next_pos - pos);
pos = next_pos;
switch (*pos)
{
case quote_character:
{
if constexpr (escape_quote_with_quote)
writeChar(quote_character, buf);
else
writeChar('\\', buf);
writeChar(quote_character, buf);
break;
}
case '\b':
writeChar('\\', buf);
writeChar('b', buf);
break;
case '\f':
writeChar('\\', buf);
writeChar('f', buf);
break;
case '\n':
writeChar('\\', buf);
writeChar('n', buf);
break;
case '\r':
writeChar('\\', buf);
writeChar('r', buf);
break;
case '\t':
writeChar('\\', buf);
writeChar('t', buf);
break;
case '\0':
writeChar('\\', buf);
writeChar('0', buf);
break;
case '\\':
if constexpr (escape_backslash_with_backslash)
writeChar('\\', buf);
writeChar('\\', buf);
break;
default:
writeChar(*pos, buf);
}
++pos;
}
}
}
inline void writeJSONString(std::string_view s, WriteBuffer & buf, const FormatSettings & settings)
{
writeJSONString(s.data(), s.data() + s.size(), buf, settings);
}
template <typename T>
void writeJSONNumber(T x, WriteBuffer & ostr, const FormatSettings & settings)
{
bool is_finite = isFinite(x);
const bool need_quote = (is_integer<T> && (sizeof(T) >= 8) && settings.json.quote_64bit_integers)
|| (settings.json.quote_denormals && !is_finite) || (is_floating_point<T> && (sizeof(T) >= 8) && settings.json.quote_64bit_floats);
if (need_quote)
writeChar('"', ostr);
if (is_finite)
writeText(x, ostr);
else if (!settings.json.quote_denormals)
writeCString("null", ostr);
else
{
if constexpr (std::is_floating_point_v<T>)
{
if (std::signbit(x))
{
if (isNaN(x))
writeCString("-nan", ostr);
else
writeCString("-inf", ostr);
}
else
{
if (isNaN(x))
writeCString("nan", ostr);
else
writeCString("inf", ostr);
}
}
}
if (need_quote)
writeChar('"', ostr);
}
template <char c>
void writeAnyEscapedString(std::string_view s, WriteBuffer & buf)
{
writeAnyEscapedString<c>(s.data(), s.data() + s.size(), buf);
}
inline void writeEscapedString(const char * str, size_t size, WriteBuffer & buf)
{
writeAnyEscapedString<'\''>(str, str + size, buf);
}
inline void writeEscapedString(std::string_view ref, WriteBuffer & buf)
{
writeEscapedString(ref.data(), ref.size(), buf);
}
template <char quote_character>
void writeAnyQuotedString(const char * begin, const char * end, WriteBuffer & buf)
{
writeChar(quote_character, buf);
writeAnyEscapedString<quote_character>(begin, end, buf);
writeChar(quote_character, buf);
}
template <char quote_character>
void writeAnyQuotedString(std::string_view ref, WriteBuffer & buf)
{
writeAnyQuotedString<quote_character>(ref.data(), ref.data() + ref.size(), buf);
}
inline void writeQuotedString(const String & s, WriteBuffer & buf)
{
writeAnyQuotedString<'\''>(s, buf);
}
inline void writeQuotedString(StringRef ref, WriteBuffer & buf)
{
writeAnyQuotedString<'\''>(ref.toView(), buf);
}
inline void writeQuotedString(std::string_view ref, WriteBuffer & buf)
{
writeAnyQuotedString<'\''>(ref.data(), ref.data() + ref.size(), buf);
}
inline void writeQuotedStringPostgreSQL(std::string_view ref, WriteBuffer & buf)
{
writeChar('\'', buf);
writeAnyEscapedString<'\'', true, false>(ref.data(), ref.data() + ref.size(), buf);
writeChar('\'', buf);
}
inline void writeDoubleQuotedString(const String & s, WriteBuffer & buf)
{
writeAnyQuotedString<'"'>(s, buf);
}
inline void writeDoubleQuotedString(StringRef s, WriteBuffer & buf)
{
writeAnyQuotedString<'"'>(s.toView(), buf);
}
inline void writeDoubleQuotedString(std::string_view s, WriteBuffer & buf)
{
writeAnyQuotedString<'"'>(s.data(), s.data() + s.size(), buf);
}
/// Outputs a string in backquotes.
inline void writeBackQuotedString(StringRef s, WriteBuffer & buf)
{
writeAnyQuotedString<'`'>(s.toView(), buf);
}
/// Outputs a string in backquotes for MySQL.
inline void writeBackQuotedStringMySQL(StringRef s, WriteBuffer & buf)
{
writeChar('`', buf);
writeAnyEscapedString<'`', true>(s.data, s.data + s.size, buf);
writeChar('`', buf);
}
/// Write quoted if the string doesn't look like and identifier.
void writeProbablyBackQuotedString(StringRef s, WriteBuffer & buf);
void writeProbablyDoubleQuotedString(StringRef s, WriteBuffer & buf);
void writeProbablyBackQuotedStringMySQL(StringRef s, WriteBuffer & buf);
/** Outputs the string in for the CSV format.
* Rules:
* - the string is outputted in quotation marks;
* - the quotation mark inside the string is outputted as two quotation marks in sequence.
*/
template <char quote = '"'>
void writeCSVString(const char * begin, const char * end, WriteBuffer & buf)
{
writeChar(quote, buf);
const char * pos = begin;
while (true)
{
const char * next_pos = find_first_symbols<quote>(pos, end);
if (next_pos == end)
{
buf.write(pos, end - pos);
break;
}
else /// Quotation.
{
++next_pos;
buf.write(pos, next_pos - pos);
writeChar(quote, buf);
}
pos = next_pos;
}
writeChar(quote, buf);
}
template <char quote = '"'>
void writeCSVString(const String & s, WriteBuffer & buf)
{
writeCSVString<quote>(s.data(), s.data() + s.size(), buf);
}
template <char quote = '"'>
void writeCSVString(StringRef s, WriteBuffer & buf)
{
writeCSVString<quote>(s.data, s.data + s.size, buf);
}
inline void writeXMLStringForTextElementOrAttributeValue(const char * begin, const char * end, WriteBuffer & buf)
{
const char * pos = begin;
while (true)
{
const char * next_pos = find_first_symbols<'<', '&', '>', '"', '\''>(pos, end);
if (next_pos == end)
{
buf.write(pos, end - pos);
break;
}
else if (*next_pos == '<')
{
buf.write(pos, next_pos - pos);
++next_pos;
writeCString("<", buf);
}
else if (*next_pos == '&')
{
buf.write(pos, next_pos - pos);
++next_pos;
writeCString("&", buf);
}
else if (*next_pos == '>')
{
buf.write(pos, next_pos - pos);
++next_pos;
writeCString(">", buf);
}
else if (*next_pos == '"')
{
buf.write(pos, next_pos - pos);
++next_pos;
writeCString(""", buf);
}
else if (*next_pos == '\'')
{
buf.write(pos, next_pos - pos);
++next_pos;
writeCString("'", buf);
}
pos = next_pos;
}
}
inline void writeXMLStringForTextElementOrAttributeValue(std::string_view s, WriteBuffer & buf)
{
writeXMLStringForTextElementOrAttributeValue(s.data(), s.data() + s.size(), buf);
}
/// Writing a string to a text node in XML (not into an attribute - otherwise you need more escaping).
inline void writeXMLStringForTextElement(const char * begin, const char * end, WriteBuffer & buf)
{
const char * pos = begin;
while (true)
{
/// NOTE Perhaps for some XML parsers, you need to escape the zero byte and some control characters.
const char * next_pos = find_first_symbols<'<', '&'>(pos, end);
if (next_pos == end)
{
buf.write(pos, end - pos);
break;
}
else if (*next_pos == '<')
{
buf.write(pos, next_pos - pos);
++next_pos;
writeCString("<", buf);
}
else if (*next_pos == '&')
{
buf.write(pos, next_pos - pos);
++next_pos;
writeCString("&", buf);
}
pos = next_pos;
}
}
inline void writeXMLStringForTextElement(std::string_view s, WriteBuffer & buf)
{
writeXMLStringForTextElement(s.data(), s.data() + s.size(), buf);
}
/// @brief Serialize `uuid` into an array of characters in big-endian byte order.
/// @param uuid UUID to serialize.
/// @return Array of characters in big-endian byte order.
std::array<char, 36> formatUUID(const UUID & uuid);
inline void writeUUIDText(const UUID & uuid, WriteBuffer & buf)
{
const auto serialized_uuid = formatUUID(uuid);
buf.write(serialized_uuid.data(), serialized_uuid.size());
}
void writeIPv4Text(const IPv4 & ip, WriteBuffer & buf);
void writeIPv6Text(const IPv6 & ip, WriteBuffer & buf);
template <typename DecimalType>
inline void writeDateTime64FractionalText(typename DecimalType::NativeType fractional, UInt32 scale, WriteBuffer & buf)
{
static constexpr UInt32 MaxScale = DecimalUtils::max_precision<DecimalType>;
char data[20] = {'0', '0', '0', '0', '0', '0', '0', '0', '0', '0', '0', '0', '0', '0', '0', '0', '0', '0'};
static_assert(sizeof(data) >= MaxScale);
for (Int32 pos = scale - 1; pos >= 0 && fractional; --pos, fractional /= DateTime64(10))
data[pos] += fractional % DateTime64(10);
writeString(&data[0], static_cast<size_t>(scale), buf);
}
static const char digits100[201] =
"00010203040506070809"
"10111213141516171819"
"20212223242526272829"
"30313233343536373839"
"40414243444546474849"
"50515253545556575859"
"60616263646566676869"
"70717273747576777879"
"80818283848586878889"
"90919293949596979899";
/// in YYYY-MM-DD format
template <char delimiter = '-'>
inline void writeDateText(const LocalDate & date, WriteBuffer & buf)
{
if (reinterpret_cast<intptr_t>(buf.position()) + 10 <= reinterpret_cast<intptr_t>(buf.buffer().end()))
{
memcpy(buf.position(), &digits100[date.year() / 100 * 2], 2);
buf.position() += 2;
memcpy(buf.position(), &digits100[date.year() % 100 * 2], 2);
buf.position() += 2;
*buf.position() = delimiter;
++buf.position();
memcpy(buf.position(), &digits100[date.month() * 2], 2);
buf.position() += 2;
*buf.position() = delimiter;
++buf.position();
memcpy(buf.position(), &digits100[date.day() * 2], 2);
buf.position() += 2;
}
else
{
buf.write(&digits100[date.year() / 100 * 2], 2);
buf.write(&digits100[date.year() % 100 * 2], 2);
buf.write(delimiter);
buf.write(&digits100[date.month() * 2], 2);
buf.write(delimiter);
buf.write(&digits100[date.day() * 2], 2);
}
}
template <char delimiter = '-'>
inline void writeDateText(DayNum date, WriteBuffer & buf, const DateLUTImpl & time_zone = DateLUT::instance())
{
writeDateText<delimiter>(LocalDate(date, time_zone), buf);
}
template <char delimiter = '-'>
inline void writeDateText(ExtendedDayNum date, WriteBuffer & buf, const DateLUTImpl & time_zone = DateLUT::instance())
{
writeDateText<delimiter>(LocalDate(date, time_zone), buf);
}
/// In the format YYYY-MM-DD HH:MM:SS
template <char date_delimeter = '-', char time_delimeter = ':', char between_date_time_delimiter = ' '>
inline void writeDateTimeText(const LocalDateTime & datetime, WriteBuffer & buf)
{
if (reinterpret_cast<intptr_t>(buf.position()) + 19 <= reinterpret_cast<intptr_t>(buf.buffer().end()))
{
memcpy(buf.position(), &digits100[datetime.year() / 100 * 2], 2);
buf.position() += 2;
memcpy(buf.position(), &digits100[datetime.year() % 100 * 2], 2);
buf.position() += 2;
*buf.position() = date_delimeter;
++buf.position();
memcpy(buf.position(), &digits100[datetime.month() * 2], 2);
buf.position() += 2;
*buf.position() = date_delimeter;
++buf.position();
memcpy(buf.position(), &digits100[datetime.day() * 2], 2);
buf.position() += 2;
*buf.position() = between_date_time_delimiter;
++buf.position();
memcpy(buf.position(), &digits100[datetime.hour() * 2], 2);
buf.position() += 2;
*buf.position() = time_delimeter;
++buf.position();
memcpy(buf.position(), &digits100[datetime.minute() * 2], 2);
buf.position() += 2;
*buf.position() = time_delimeter;
++buf.position();
memcpy(buf.position(), &digits100[datetime.second() * 2], 2);
buf.position() += 2;
}
else
{
buf.write(&digits100[datetime.year() / 100 * 2], 2);
buf.write(&digits100[datetime.year() % 100 * 2], 2);
buf.write(date_delimeter);
buf.write(&digits100[datetime.month() * 2], 2);
buf.write(date_delimeter);
buf.write(&digits100[datetime.day() * 2], 2);
buf.write(between_date_time_delimiter);
buf.write(&digits100[datetime.hour() * 2], 2);
buf.write(time_delimeter);
buf.write(&digits100[datetime.minute() * 2], 2);
buf.write(time_delimeter);
buf.write(&digits100[datetime.second() * 2], 2);
}
}
/// In the format YYYY-MM-DD HH:MM:SS, according to the specified time zone.
template <char date_delimeter = '-', char time_delimeter = ':', char between_date_time_delimiter = ' '>
inline void writeDateTimeText(time_t datetime, WriteBuffer & buf, const DateLUTImpl & time_zone = DateLUT::instance())
{
writeDateTimeText<date_delimeter, time_delimeter, between_date_time_delimiter>(LocalDateTime(datetime, time_zone), buf);
}
/// In the format YYYY-MM-DD HH:MM:SS.NNNNNNNNN, according to the specified time zone.
template <char date_delimeter = '-', char time_delimeter = ':', char between_date_time_delimiter = ' ', char fractional_time_delimiter = '.'>
inline void writeDateTimeText(DateTime64 datetime64, UInt32 scale, WriteBuffer & buf, const DateLUTImpl & time_zone = DateLUT::instance())
{
static constexpr UInt32 MaxScale = DecimalUtils::max_precision<DateTime64>;
scale = scale > MaxScale ? MaxScale : scale;
auto components = DecimalUtils::split(datetime64, scale);
/// Case1:
/// -127914467.877
/// => whole = -127914467, fraction = 877(After DecimalUtils::split)
/// => new whole = -127914468(1965-12-12 12:12:12), new fraction = 1000 - 877 = 123(.123)
/// => 1965-12-12 12:12:12.123
///
/// Case2:
/// -0.877
/// => whole = 0, fractional = -877(After DecimalUtils::split)
/// => whole = -1(1969-12-31 23:59:59), fractional = 1000 + (-877) = 123(.123)
using T = typename DateTime64::NativeType;
if (datetime64.value < 0 && components.fractional)
{
components.fractional = DecimalUtils::scaleMultiplier<T>(scale) + (components.whole ? T(-1) : T(1)) * components.fractional;
--components.whole;
}
writeDateTimeText<date_delimeter, time_delimeter, between_date_time_delimiter>(LocalDateTime(components.whole, time_zone), buf);
if (scale > 0)
{
buf.write(fractional_time_delimiter);
writeDateTime64FractionalText<DateTime64>(components.fractional, scale, buf);
}
}
/// In the RFC 1123 format: "Tue, 03 Dec 2019 00:11:50 GMT". You must provide GMT DateLUT.
/// This is needed for HTTP requests.
inline void writeDateTimeTextRFC1123(time_t datetime, WriteBuffer & buf, const DateLUTImpl & time_zone = DateLUT::instance())
{
const auto & values = time_zone.getValues(datetime);
static const char week_days[3 * 8 + 1] = "XXX" "Mon" "Tue" "Wed" "Thu" "Fri" "Sat" "Sun";
static const char months[3 * 13 + 1] = "XXX" "Jan" "Feb" "Mar" "Apr" "May" "Jun" "Jul" "Aug" "Sep" "Oct" "Nov" "Dec";
buf.write(&week_days[values.day_of_week * 3], 3);
buf.write(", ", 2);
buf.write(&digits100[values.day_of_month * 2], 2);
buf.write(' ');
buf.write(&months[values.month * 3], 3);
buf.write(' ');
buf.write(&digits100[values.year / 100 * 2], 2);
buf.write(&digits100[values.year % 100 * 2], 2);
buf.write(' ');
buf.write(&digits100[time_zone.toHour(datetime) * 2], 2);
buf.write(':');
buf.write(&digits100[time_zone.toMinute(datetime) * 2], 2);
buf.write(':');
buf.write(&digits100[time_zone.toSecond(datetime) * 2], 2);
buf.write(" GMT", 4);
}
inline void writeDateTimeTextISO(time_t datetime, WriteBuffer & buf, const DateLUTImpl & utc_time_zone)
{
writeDateTimeText<'-', ':', 'T'>(datetime, buf, utc_time_zone);
buf.write('Z');
}
inline void writeDateTimeTextISO(DateTime64 datetime64, UInt32 scale, WriteBuffer & buf, const DateLUTImpl & utc_time_zone)
{
writeDateTimeText<'-', ':', 'T'>(datetime64, scale, buf, utc_time_zone);
buf.write('Z');
}
inline void writeDateTimeUnixTimestamp(DateTime64 datetime64, UInt32 scale, WriteBuffer & buf)
{
static constexpr UInt32 MaxScale = DecimalUtils::max_precision<DateTime64>;
scale = scale > MaxScale ? MaxScale : scale;
auto components = DecimalUtils::split(datetime64, scale);
writeIntText(components.whole, buf);
if (scale > 0)
{
buf.write('.');
writeDateTime64FractionalText<DateTime64>(components.fractional, scale, buf);
}
}
/// Methods for output in binary format.
template <typename T>
requires is_arithmetic_v<T>
inline void writeBinary(const T & x, WriteBuffer & buf) { writePODBinary(x, buf); }
inline void writeBinary(const String & x, WriteBuffer & buf) { writeStringBinary(x, buf); }
inline void writeBinary(StringRef x, WriteBuffer & buf) { writeStringBinary(x, buf); }
inline void writeBinary(std::string_view x, WriteBuffer & buf) { writeStringBinary(x, buf); }
inline void writeBinary(const Decimal32 & x, WriteBuffer & buf) { writePODBinary(x, buf); }
inline void writeBinary(const Decimal64 & x, WriteBuffer & buf) { writePODBinary(x, buf); }
inline void writeBinary(const Decimal128 & x, WriteBuffer & buf) { writePODBinary(x, buf); }
inline void writeBinary(const Decimal256 & x, WriteBuffer & buf) { writePODBinary(x.value, buf); }
inline void writeBinary(const LocalDate & x, WriteBuffer & buf) { writePODBinary(x, buf); }
inline void writeBinary(const LocalDateTime & x, WriteBuffer & buf) { writePODBinary(x, buf); }
inline void writeBinary(const IPv4 & x, WriteBuffer & buf) { writePODBinary(x, buf); }
inline void writeBinary(const IPv6 & x, WriteBuffer & buf) { writePODBinary(x, buf); }
inline void writeBinary(const UUID & x, WriteBuffer & buf)
{
writeUUIDBinary(x, buf);
}
inline void writeBinary(const CityHash_v1_0_2::uint128 & x, WriteBuffer & buf)
{
writePODBinary(x.low64, buf);
writePODBinary(x.high64, buf);
}
inline void writeBinary(const StackTrace::FramePointers & x, WriteBuffer & buf) { writePODBinary(x, buf); }
/// Methods for outputting the value in text form for a tab-separated format.
inline void writeText(is_integer auto x, WriteBuffer & buf)
{
if constexpr (std::is_same_v<decltype(x), bool>)
writeBoolText(x, buf);
else if constexpr (std::is_same_v<decltype(x), char>)
writeChar(x, buf);
else
writeIntText(x, buf);
}
inline void writeText(is_floating_point auto x, WriteBuffer & buf) { writeFloatText(x, buf); }
inline void writeText(is_enum auto x, WriteBuffer & buf) { writeText(magic_enum::enum_name(x), buf); }
inline void writeText(std::string_view x, WriteBuffer & buf) { writeString(x.data(), x.size(), buf); }
inline void writeText(const DayNum & x, WriteBuffer & buf, const DateLUTImpl & time_zone = DateLUT::instance()) { writeDateText(LocalDate(x, time_zone), buf); }
inline void writeText(const LocalDate & x, WriteBuffer & buf) { writeDateText(x, buf); }
inline void writeText(const LocalDateTime & x, WriteBuffer & buf) { writeDateTimeText(x, buf); }
inline void writeText(const UUID & x, WriteBuffer & buf) { writeUUIDText(x, buf); }
inline void writeText(const IPv4 & x, WriteBuffer & buf) { writeIPv4Text(x, buf); }
inline void writeText(const IPv6 & x, WriteBuffer & buf) { writeIPv6Text(x, buf); }
template <typename T>
void writeDecimalFractional(const T & x, UInt32 scale, WriteBuffer & ostr, bool trailing_zeros,
bool fixed_fractional_length, UInt32 fractional_length)
{
/// If it's big integer, but the number of digits is small,
/// use the implementation for smaller integers for more efficient arithmetic.
if constexpr (std::is_same_v<T, Int256>)
{
if (x <= std::numeric_limits<UInt32>::max())
{
writeDecimalFractional(static_cast<UInt32>(x), scale, ostr, trailing_zeros, fixed_fractional_length, fractional_length);
return;
}
else if (x <= std::numeric_limits<UInt64>::max())
{
writeDecimalFractional(static_cast<UInt64>(x), scale, ostr, trailing_zeros, fixed_fractional_length, fractional_length);
return;
}
else if (x <= std::numeric_limits<UInt128>::max())
{
writeDecimalFractional(static_cast<UInt128>(x), scale, ostr, trailing_zeros, fixed_fractional_length, fractional_length);
return;
}
}
else if constexpr (std::is_same_v<T, Int128>)
{
if (x <= std::numeric_limits<UInt32>::max())
{
writeDecimalFractional(static_cast<UInt32>(x), scale, ostr, trailing_zeros, fixed_fractional_length, fractional_length);
return;
}
else if (x <= std::numeric_limits<UInt64>::max())
{
writeDecimalFractional(static_cast<UInt64>(x), scale, ostr, trailing_zeros, fixed_fractional_length, fractional_length);
return;
}
}
constexpr size_t max_digits = std::numeric_limits<UInt256>::digits10;
assert(scale <= max_digits);
assert(fractional_length <= max_digits);
char buf[max_digits];
memset(buf, '0', std::max(scale, fractional_length));
T value = x;
Int32 last_nonzero_pos = 0;
if (fixed_fractional_length && fractional_length < scale)
{
T new_value = value / DecimalUtils::scaleMultiplier<Int256>(scale - fractional_length - 1);
auto round_carry = new_value % 10;
value = new_value / 10;
if (round_carry >= 5)
value += 1;
}
for (Int32 pos = fixed_fractional_length ? std::min(scale - 1, fractional_length - 1) : scale - 1; pos >= 0; --pos)
{
auto remainder = value % 10;
value /= 10;
if (remainder != 0 && last_nonzero_pos == 0)
last_nonzero_pos = pos;
buf[pos] += static_cast<char>(remainder);
}
writeChar('.', ostr);
ostr.write(buf, fixed_fractional_length ? fractional_length : (trailing_zeros ? scale : last_nonzero_pos + 1));
}
template <typename T>
void writeText(Decimal<T> x, UInt32 scale, WriteBuffer & ostr, bool trailing_zeros,
bool fixed_fractional_length = false, UInt32 fractional_length = 0)
{
T part = DecimalUtils::getWholePart(x, scale);
if (x.value < 0 && part == 0)
{
writeChar('-', ostr); /// avoid crop leading minus when whole part is zero
}
writeIntText(part, ostr);
if (scale || (fixed_fractional_length && fractional_length > 0))
{
part = DecimalUtils::getFractionalPart(x, scale);
if (part || trailing_zeros)
{
if (part < 0)
part *= T(-1);
writeDecimalFractional(part, scale, ostr, trailing_zeros, fixed_fractional_length, fractional_length);
}
}
}
/// String, date, datetime are in single quotes with C-style escaping. Numbers - without.
template <typename T>
requires is_arithmetic_v<T>
inline void writeQuoted(const T & x, WriteBuffer & buf) { writeText(x, buf); }
inline void writeQuoted(const String & x, WriteBuffer & buf) { writeQuotedString(x, buf); }
inline void writeQuoted(std::string_view x, WriteBuffer & buf) { writeQuotedString(x, buf); }
inline void writeQuoted(StringRef x, WriteBuffer & buf) { writeQuotedString(x, buf); }
inline void writeQuoted(const LocalDate & x, WriteBuffer & buf)
{
writeChar('\'', buf);
writeDateText(x, buf);
writeChar('\'', buf);
}
inline void writeQuoted(const LocalDateTime & x, WriteBuffer & buf)
{
writeChar('\'', buf);
writeDateTimeText(x, buf);
writeChar('\'', buf);
}
inline void writeQuoted(const UUID & x, WriteBuffer & buf)
{
writeChar('\'', buf);
writeText(x, buf);
writeChar('\'', buf);
}
inline void writeQuoted(const IPv4 & x, WriteBuffer & buf)
{
writeChar('\'', buf);
writeText(x, buf);
writeChar('\'', buf);
}
inline void writeQuoted(const IPv6 & x, WriteBuffer & buf)
{
writeChar('\'', buf);
writeText(x, buf);
writeChar('\'', buf);
}
/// String, date, datetime are in double quotes with C-style escaping. Numbers - without.
template <typename T>
requires is_arithmetic_v<T>
inline void writeDoubleQuoted(const T & x, WriteBuffer & buf) { writeText(x, buf); }
inline void writeDoubleQuoted(const String & x, WriteBuffer & buf) { writeDoubleQuotedString(x, buf); }
inline void writeDoubleQuoted(std::string_view x, WriteBuffer & buf) { writeDoubleQuotedString(x, buf); }
inline void writeDoubleQuoted(StringRef x, WriteBuffer & buf) { writeDoubleQuotedString(x, buf); }
inline void writeDoubleQuoted(const LocalDate & x, WriteBuffer & buf)
{
writeChar('"', buf);
writeDateText(x, buf);
writeChar('"', buf);
}
inline void writeDoubleQuoted(const LocalDateTime & x, WriteBuffer & buf)
{
writeChar('"', buf);
writeDateTimeText(x, buf);
writeChar('"', buf);
}
inline void writeDoubleQuoted(const UUID & x, WriteBuffer & buf)
{
writeChar('"', buf);
writeText(x, buf);
writeChar('"', buf);
}
inline void writeDoubleQuoted(const IPv4 & x, WriteBuffer & buf)
{
writeChar('"', buf);
writeText(x, buf);
writeChar('"', buf);
}
inline void writeDoubleQuoted(const IPv6 & x, WriteBuffer & buf)
{
writeChar('"', buf);
writeText(x, buf);
writeChar('"', buf);
}
/// String - in double quotes and with CSV-escaping; date, datetime - in double quotes. Numbers - without.
template <typename T>
requires is_arithmetic_v<T>
inline void writeCSV(const T & x, WriteBuffer & buf) { writeText(x, buf); }
inline void writeCSV(const String & x, WriteBuffer & buf) { writeCSVString<>(x, buf); }
inline void writeCSV(const LocalDate & x, WriteBuffer & buf) { writeDoubleQuoted(x, buf); }
inline void writeCSV(const LocalDateTime & x, WriteBuffer & buf) { writeDoubleQuoted(x, buf); }
inline void writeCSV(const UUID & x, WriteBuffer & buf) { writeDoubleQuoted(x, buf); }
inline void writeCSV(const IPv4 & x, WriteBuffer & buf) { writeDoubleQuoted(x, buf); }
inline void writeCSV(const IPv6 & x, WriteBuffer & buf) { writeDoubleQuoted(x, buf); }
template <typename T>
void writeBinary(const std::vector<T> & x, WriteBuffer & buf)
{
size_t size = x.size();
writeVarUInt(size, buf);
for (size_t i = 0; i < size; ++i)
writeBinary(x[i], buf);
}
template <typename T>
void writeQuoted(const std::vector<T> & x, WriteBuffer & buf)
{
writeChar('[', buf);
for (size_t i = 0, size = x.size(); i < size; ++i)
{
if (i != 0)
writeChar(',', buf);
writeQuoted(x[i], buf);
}
writeChar(']', buf);
}
template <typename T>
void writeDoubleQuoted(const std::vector<T> & x, WriteBuffer & buf)
{
writeChar('[', buf);
for (size_t i = 0, size = x.size(); i < size; ++i)
{
if (i != 0)
writeChar(',', buf);
writeDoubleQuoted(x[i], buf);
}
writeChar(']', buf);
}
template <typename T>
void writeText(const std::vector<T> & x, WriteBuffer & buf)
{
writeQuoted(x, buf);
}
/// Serialize exception (so that it can be transferred over the network)
void writeException(const Exception & e, WriteBuffer & buf, bool with_stack_trace);
/// An easy-to-use method for converting something to a string in text form.
template <typename T>
inline String toString(const T & x)
{
WriteBufferFromOwnString buf;
writeText(x, buf);
return buf.str();
}
inline String toString(const CityHash_v1_0_2::uint128 & hash)
{
WriteBufferFromOwnString buf;
writeText(hash.low64, buf);
writeChar('_', buf);
writeText(hash.high64, buf);
return buf.str();
}
template <typename T>
inline String toStringWithFinalSeparator(const std::vector<T> & x, const String & final_sep)
{
WriteBufferFromOwnString buf;
for (auto it = x.begin(); it != x.end(); ++it)
{
if (it != x.begin())
{
if (std::next(it) == x.end())
writeString(final_sep, buf);
else
writeString(", ", buf);
}
writeQuoted(*it, buf);
}
return buf.str();
}
inline void writeNullTerminatedString(const String & s, WriteBuffer & buffer)
{
/// c_str is guaranteed to return zero-terminated string
buffer.write(s.c_str(), s.size() + 1);
}
template <std::endian endian, typename T>
inline void writeBinaryEndian(T x, WriteBuffer & buf)
{
transformEndianness<endian>(x);
writeBinary(x, buf);
}
template <typename T>
inline void writeBinaryLittleEndian(T x, WriteBuffer & buf)
{
writeBinaryEndian<std::endian::little>(x, buf);
}
template <typename T>
inline void writeBinaryBigEndian(T x, WriteBuffer & buf)
{
writeBinaryEndian<std::endian::big>(x, buf);
}
struct PcgSerializer
{
static void serializePcg32(const pcg32_fast & rng, WriteBuffer & buf)
{
writeText(rng.multiplier(), buf);
writeChar(' ', buf);
writeText(rng.increment(), buf);
writeChar(' ', buf);
writeText(rng.state_, buf);
}
};
void writePointerHex(const void * ptr, WriteBuffer & buf);
}
template<>
struct fmt::formatter<DB::UUID>
{
template<typename ParseContext>
constexpr auto parse(ParseContext & context)
{
return context.begin();
}
template<typename FormatContext>
auto format(const DB::UUID & uuid, FormatContext & context)
{
return fmt::format_to(context.out(), "{}", toString(uuid));
}
};
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