mirror of
https://github.com/zerotier/ZeroTierOne.git
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be7ce4110e
This reverts commit e96515433d
.
469 lines
16 KiB
C++
469 lines
16 KiB
C++
/* String conversion definitions.
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*
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* DO NOT INCLUDE THIS FILE DIRECTLY; include pqxx/stringconv instead.
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*
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* Copyright (c) 2000-2022, Jeroen T. Vermeulen.
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*
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* See COPYING for copyright license. If you did not receive a file called
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* COPYING with this source code, please notify the distributor of this
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* mistake, or contact the author.
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*/
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#ifndef PQXX_H_STRCONV
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#define PQXX_H_STRCONV
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#if !defined(PQXX_HEADER_PRE)
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# error "Include libpqxx headers as <pqxx/header>, not <pqxx/header.hxx>."
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#endif
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#include <algorithm>
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#include <cstring>
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#include <limits>
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#include <sstream>
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#include <stdexcept>
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#include <typeinfo>
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#if __has_include(<charconv>)
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# include <charconv>
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#endif
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#if defined(PQXX_HAVE_RANGES) && __has_include(<ranges>)
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# include <ranges>
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#endif
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#include "pqxx/except.hxx"
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#include "pqxx/util.hxx"
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#include "pqxx/zview.hxx"
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namespace pqxx::internal
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{
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/// Attempt to demangle @c std::type_info::name() to something human-readable.
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PQXX_LIBEXPORT std::string demangle_type_name(char const[]);
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} // namespace pqxx::internal
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namespace pqxx
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{
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/**
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* @defgroup stringconversion String conversion
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*
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* The PostgreSQL server accepts and represents data in string form. It has
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* its own formats for various data types. The string conversions define how
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* various C++ types translate to and from their respective PostgreSQL text
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* representations.
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*
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* Each conversion is defined by a specialisations of @c string_traits. It
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* gets complicated if you want top performance, but until you do, all you
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* really need to care about when converting values between C++ in-memory
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* representations such as @c int and the postgres string representations is
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* the @c pqxx::to_string and @c pqxx::from_string functions.
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*
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* If you need to convert a type which is not supported out of the box, you'll
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* need to define your own specialisations for these templates, similar to the
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* ones defined here and in `pqxx/conversions.hxx`. Any conversion code which
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* "sees" your specialisation will now support your conversion. In particular,
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* you'll be able to read result fields into a variable of the new type.
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*
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* There is a macro to help you define conversions for individual enumeration
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* types. The conversion will represent enumeration values as numeric strings.
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*/
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//@{
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/// A human-readable name for a type, used in error messages and such.
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/** Actually this may not always be very user-friendly. It uses
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* @c std::type_info::name(). On gcc-like compilers we try to demangle its
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* output. Visual Studio produces human-friendly names out of the box.
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*
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* This variable is not inline. Inlining it gives rise to "memory leak"
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* warnings from asan, the address sanitizer, possibly from use of
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* @c std::type_info::name.
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*/
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template<typename TYPE>
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std::string const type_name{internal::demangle_type_name(typeid(TYPE).name())};
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/// Traits describing a type's "null value," if any.
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/** Some C++ types have a special value or state which correspond directly to
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* SQL's NULL.
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*
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* The @c nullness traits describe whether it exists, and whether a particular
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* value is null.
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*/
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template<typename TYPE, typename ENABLE = void> struct nullness
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{
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/// Does this type have a null value?
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static bool has_null;
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/// Is this type always null?
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static bool always_null;
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/// Is @c value a null?
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static bool is_null(TYPE const &value);
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/// Return a null value.
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/** Don't use this in generic code to compare a value and see whether it is
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* null. Some types may have multiple null values which do not compare as
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* equal, or may define a null value which is not equal to anything including
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* itself, like in SQL.
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*/
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[[nodiscard]] static TYPE null();
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};
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/// Nullness traits describing a type which does not have a null value.
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template<typename TYPE> struct no_null
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{
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/// Does @c TYPE have a "built-in null value"?
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/** For example, a pointer can equal @c nullptr, which makes a very natural
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* representation of an SQL null value. For such types, the code sometimes
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* needs to make special allowances.
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*
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* for most types, such as @c int or @c std::string, there is no built-in
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* null. If you want to represent an SQL null value for such a type, you
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* would have to wrap it in something that does have a null value. For
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* example, you could use @c std::optional<int> for "either an @c int or a
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* null value."
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*/
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static constexpr bool has_null = false;
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/// Are all values of this type null?
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/** There are a few special C++ types which are always null - mainly
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* @c std::nullptr_t.
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*/
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static constexpr bool always_null = false;
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/// Does a given value correspond to an SQL null value?
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/** Most C++ types, such as @c int or @c std::string, have no inherent null
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* value. But some types such as C-style string pointers do have a natural
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* equivalent to an SQL null.
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*/
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[[nodiscard]] static constexpr bool is_null(TYPE const &) noexcept
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{
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return false;
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}
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};
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/// Traits class for use in string conversions.
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/** Specialize this template for a type for which you wish to add to_string
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* and from_string support.
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*
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* String conversions are not meant to work for nulls. Check for null before
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* converting a value of @c TYPE to a string, or vice versa.
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*/
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template<typename TYPE> struct string_traits
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{
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/// Return a @c string_view representing value, plus terminating zero.
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/** Produces a @c string_view containing the PostgreSQL string representation
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* for @c value.
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*
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* Uses the space from @c begin to @c end as a buffer, if needed. The
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* returned string may lie somewhere in that buffer, or it may be a
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* compile-time constant, or it may be null if value was a null value. Even
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* if the string is stored in the buffer, its @c begin() may or may not be
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* the same as @c begin.
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*
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* The @c string_view is guaranteed to be valid as long as the buffer from
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* @c begin to @c end remains accessible and unmodified.
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*
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* @throws pqxx::conversion_overrun if the provided buffer space may not be
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* enough. For maximum performance, this is a conservative estimate. It may
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* complain about a buffer which is actually large enough for your value, if
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* an exact check gets too expensive.
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*/
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[[nodiscard]] static inline zview
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to_buf(char *begin, char *end, TYPE const &value);
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/// Write value's string representation into buffer at @c begin.
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/** Assumes that value is non-null.
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*
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* Writes value's string representation into the buffer, starting exactly at
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* @c begin, and ensuring a trailing zero. Returns the address just beyond
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* the trailing zero, so the caller could use it as the @c begin for another
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* call to @c into_buf writing a next value.
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*/
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static inline char *into_buf(char *begin, char *end, TYPE const &value);
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/// Parse a string representation of a @c TYPE value.
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/** Throws @c conversion_error if @c value does not meet the expected format
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* for a value of this type.
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*/
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[[nodiscard]] static inline TYPE from_string(std::string_view text);
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// C++20: Can we make these all constexpr?
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/// Estimate how much buffer space is needed to represent value.
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/** The estimate may be a little pessimistic, if it saves time.
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*
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* The estimate includes the terminating zero.
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*/
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[[nodiscard]] static inline std::size_t
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size_buffer(TYPE const &value) noexcept;
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};
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/// Nullness: Enums do not have an inherent null value.
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template<typename ENUM>
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struct nullness<ENUM, std::enable_if_t<std::is_enum_v<ENUM>>> : no_null<ENUM>
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{};
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} // namespace pqxx
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namespace pqxx::internal
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{
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/// Helper class for defining enum conversions.
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/** The conversion will convert enum values to numeric strings, and vice versa.
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*
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* To define a string conversion for an enum type, derive a @c string_traits
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* specialisation for the enum from this struct.
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*
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* There's usually an easier way though: the @c PQXX_DECLARE_ENUM_CONVERSION
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* macro. Use @c enum_traits manually only if you need to customise your
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* traits type in more detail.
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*/
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template<typename ENUM> struct enum_traits
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{
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using impl_type = std::underlying_type_t<ENUM>;
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using impl_traits = string_traits<impl_type>;
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[[nodiscard]] static constexpr zview
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to_buf(char *begin, char *end, ENUM const &value)
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{
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return impl_traits::to_buf(begin, end, to_underlying(value));
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}
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static constexpr char *into_buf(char *begin, char *end, ENUM const &value)
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{
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return impl_traits::into_buf(begin, end, to_underlying(value));
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}
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[[nodiscard]] static ENUM from_string(std::string_view text)
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{
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return static_cast<ENUM>(impl_traits::from_string(text));
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}
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[[nodiscard]] static std::size_t size_buffer(ENUM const &value) noexcept
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{
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return impl_traits::size_buffer(to_underlying(value));
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}
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private:
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// C++23: Replace with std::to_underlying.
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static constexpr impl_type to_underlying(ENUM const &value) noexcept
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{
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return static_cast<impl_type>(value);
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}
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};
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} // namespace pqxx::internal
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/// Macro: Define a string conversion for an enum type.
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/** This specialises the @c pqxx::string_traits template, so use it in the
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* @c ::pqxx namespace.
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*
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* For example:
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*
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* #include <iostream>
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* #include <pqxx/strconv>
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* enum X { xa, xb };
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* namespace pqxx { PQXX_DECLARE_ENUM_CONVERSION(x); }
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* int main() { std::cout << pqxx::to_string(xa) << std::endl; }
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*/
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#define PQXX_DECLARE_ENUM_CONVERSION(ENUM) \
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template<> struct string_traits<ENUM> : pqxx::internal::enum_traits<ENUM> \
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{}; \
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template<> inline std::string const type_name<ENUM> { #ENUM }
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namespace pqxx
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{
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/// Parse a value in postgres' text format as a TYPE.
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/** If the form of the value found in the string does not match the expected
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* type, e.g. if a decimal point is found when converting to an integer type,
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* the conversion fails. Overflows (e.g. converting "9999999999" to a 16-bit
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* C++ type) are also treated as errors. If in some cases this behaviour
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* should be inappropriate, convert to something bigger such as @c long @c int
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* first and then truncate the resulting value.
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*
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* Only the simplest possible conversions are supported. Fancy features like
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* hexadecimal or octal, spurious signs, or exponent notation won't work.
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* Whitespace is not stripped away. Only the kinds of strings that come out of
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* PostgreSQL and out of to_string() can be converted.
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*/
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template<typename TYPE>
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[[nodiscard]] inline TYPE from_string(std::string_view text)
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{
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return string_traits<TYPE>::from_string(text);
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}
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/// "Convert" a std::string_view to a std::string_view.
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/** Just returns its input.
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*
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* @warning Of course the result is only valid for as long as the original
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* string remains valid! Never access the string referenced by the return
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* value after the original has been destroyed.
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*/
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template<>
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[[nodiscard]] inline std::string_view from_string(std::string_view text)
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{
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return text;
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}
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/// Attempt to convert postgres-generated string to given built-in object.
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/** This is like the single-argument form of the function, except instead of
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* returning the value, it sets @c value.
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*
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* You may find this more convenient in that it infers the type you want from
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* the argument you pass. But there are disadvantages: it requires an
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* assignment operator, and it may be less efficient.
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*/
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template<typename T> inline void from_string(std::string_view text, T &value)
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{
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value = from_string<T>(text);
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}
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/// Convert a value to a readable string that PostgreSQL will understand.
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/** The conversion does no special formatting, and ignores any locale settings.
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* The resulting string will be human-readable and in a format suitable for use
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* in SQL queries. It won't have niceties such as "thousands separators"
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* though.
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*/
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template<typename TYPE> inline std::string to_string(TYPE const &value);
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/// Convert multiple values to strings inside a single buffer.
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/** There must be enough room for all values, or this will throw
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* @c conversion_overrun. You can obtain a conservative estimate of the buffer
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* space required by calling @c size_buffer() on the values.
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*
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* The @c std::string_view results may point into the buffer, so don't assume
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* that they will remain valid after you destruct or move the buffer.
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*/
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template<typename... TYPE>
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[[nodiscard]] inline std::vector<std::string_view>
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to_buf(char *here, char const *end, TYPE... value)
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{
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return {[&here, end](auto v) {
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auto begin = here;
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here = string_traits<decltype(v)>::into_buf(begin, end, v);
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// Exclude the trailing zero out of the string_view.
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auto len{static_cast<std::size_t>(here - begin) - 1};
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return std::string_view{begin, len};
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}(value)...};
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}
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/// Convert a value to a readable string that PostgreSQL will understand.
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/** This variant of to_string can sometimes save a bit of time in loops, by
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* re-using a std::string for multiple conversions.
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*/
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template<typename TYPE>
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inline void into_string(TYPE const &value, std::string &out);
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/// Is @c value null?
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template<typename TYPE>
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[[nodiscard]] inline constexpr bool is_null(TYPE const &value) noexcept
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{
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return nullness<strip_t<TYPE>>::is_null(value);
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}
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/// Estimate how much buffer space is needed to represent values as a string.
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/** The estimate may be a little pessimistic, if it saves time. It also
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* includes room for a terminating zero after each value.
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*/
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template<typename... TYPE>
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[[nodiscard]] inline std::size_t size_buffer(TYPE const &...value) noexcept
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{
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return (string_traits<strip_t<TYPE>>::size_buffer(value) + ...);
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}
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/// Does this type translate to an SQL array?
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/** Specialisations may override this to be true for container types.
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*
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* This may not always be a black-and-white choice. For instance, a
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* @c std::string is a container, but normally it translates to an SQL string,
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* not an SQL array.
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*/
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template<typename TYPE> inline constexpr bool is_sql_array{false};
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/// Can we use this type in arrays and composite types without quoting them?
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/** Define this as @c true only if values of @c TYPE can never contain any
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* special characters that might need escaping or confuse the parsing of array
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* or composite * types, such as commas, quotes, parentheses, braces, newlines,
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* and so on.
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*
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* When converting a value of such a type to a string in an array or a field in
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* a composite type, we do not need to add quotes, nor escape any special
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* characters.
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*
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* This is just an optimisation, so it defaults to @c false to err on the side
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* of slow correctness.
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*/
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template<typename TYPE> inline constexpr bool is_unquoted_safe{false};
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/// Element separator between SQL array elements of this type.
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template<typename T> inline constexpr char array_separator{','};
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/// What's the preferred format for passing non-null parameters of this type?
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/** This affects how we pass parameters of @c TYPE when calling parameterised
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* statements or prepared statements.
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*
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* Generally we pass parameters in text format, but binary strings are the
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* exception. We also pass nulls in binary format, so this function need not
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* handle null values.
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*/
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template<typename TYPE> inline constexpr format param_format(TYPE const &)
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{
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return format::text;
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}
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/// Implement @c string_traits<TYPE>::to_buf by calling @c into_buf.
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/** When you specialise @c string_traits for a new type, most of the time its
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* @c to_buf implementation has no special optimisation tricks and just writes
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* its text into the buffer it receives from the caller, starting at the
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* beginning.
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*
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* In that common situation, you can implement @c to_buf as just a call to
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* @c generic_to_buf. It will call @c into_buf and return the right result for
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* @c to_buf.
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*/
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template<typename TYPE>
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inline zview generic_to_buf(char *begin, char *end, TYPE const &value)
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{
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using traits = string_traits<TYPE>;
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// The trailing zero does not count towards the zview's size, so subtract 1
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// from the result we get from into_buf().
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if (is_null(value))
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return {};
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else
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return {begin, traits::into_buf(begin, end, value) - begin - 1};
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}
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#if defined(PQXX_HAVE_CONCEPTS)
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/// Concept: Binary string, akin to @c std::string for binary data.
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/** Any type that satisfies this concept can represent an SQL BYTEA value.
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*
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* A @c binary has a @c begin(), @c end(), @c size(), and @data(). Each byte
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* is a @c std::byte, and they must all be laid out contiguously in memory so
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* we can reference them by a pointer.
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*/
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template<class TYPE>
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concept binary = std::ranges::contiguous_range<TYPE> and
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std::is_same_v<strip_t<value_type<TYPE>>, std::byte>;
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#endif
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//@}
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} // namespace pqxx
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#include "pqxx/internal/conversions.hxx"
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#endif
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