/* * Copyright 2016 Facebook, Inc. * * Licensed under the Apache License, Version 2.0 (the "License"); * you may not use this file except in compliance with the License. * You may obtain a copy of the License at * * http://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. */ #ifndef FOLLY_FORMAT_H_ #error This file may only be included from Format.h. #endif #include #include #include #include #include #include #include #include #include #include // Ignore -Wformat-nonliteral warnings within this file #pragma GCC diagnostic push #pragma GCC diagnostic ignored "-Wformat-nonliteral" namespace folly { namespace detail { // Updates the end of the buffer after the comma separators have been added. void insertThousandsGroupingUnsafe(char* start_buffer, char** end_buffer); extern const char formatHexUpper[256][2]; extern const char formatHexLower[256][2]; extern const char formatOctal[512][3]; extern const char formatBinary[256][8]; const size_t kMaxHexLength = 2 * sizeof(uintmax_t); const size_t kMaxOctalLength = 3 * sizeof(uintmax_t); const size_t kMaxBinaryLength = 8 * sizeof(uintmax_t); /** * Convert an unsigned to hex, using repr (which maps from each possible * 2-hex-bytes value to the 2-character representation). * * Just like folly::detail::uintToBuffer in Conv.h, writes at the *end* of * the supplied buffer and returns the offset of the beginning of the string * from the start of the buffer. The formatted string will be in range * [buf+begin, buf+bufLen). */ template size_t uintToHex(char* buffer, size_t bufLen, Uint v, const char (&repr)[256][2]) { // 'v >>= 7, v >>= 1' is no more than a work around to get rid of shift size // warning when Uint = uint8_t (it's false as v >= 256 implies sizeof(v) > 1). for (; !less_than(v); v >>= 7, v >>= 1) { auto b = v & 0xff; bufLen -= 2; buffer[bufLen] = repr[b][0]; buffer[bufLen + 1] = repr[b][1]; } buffer[--bufLen] = repr[v][1]; if (v >= 16) { buffer[--bufLen] = repr[v][0]; } return bufLen; } /** * Convert an unsigned to hex, using lower-case letters for the digits * above 9. See the comments for uintToHex. */ template inline size_t uintToHexLower(char* buffer, size_t bufLen, Uint v) { return uintToHex(buffer, bufLen, v, formatHexLower); } /** * Convert an unsigned to hex, using upper-case letters for the digits * above 9. See the comments for uintToHex. */ template inline size_t uintToHexUpper(char* buffer, size_t bufLen, Uint v) { return uintToHex(buffer, bufLen, v, formatHexUpper); } /** * Convert an unsigned to octal. * * Just like folly::detail::uintToBuffer in Conv.h, writes at the *end* of * the supplied buffer and returns the offset of the beginning of the string * from the start of the buffer. The formatted string will be in range * [buf+begin, buf+bufLen). */ template size_t uintToOctal(char* buffer, size_t bufLen, Uint v) { auto& repr = formatOctal; // 'v >>= 7, v >>= 2' is no more than a work around to get rid of shift size // warning when Uint = uint8_t (it's false as v >= 512 implies sizeof(v) > 1). for (; !less_than(v); v >>= 7, v >>= 2) { auto b = v & 0x1ff; bufLen -= 3; buffer[bufLen] = repr[b][0]; buffer[bufLen + 1] = repr[b][1]; buffer[bufLen + 2] = repr[b][2]; } buffer[--bufLen] = repr[v][2]; if (v >= 8) { buffer[--bufLen] = repr[v][1]; } if (v >= 64) { buffer[--bufLen] = repr[v][0]; } return bufLen; } /** * Convert an unsigned to binary. * * Just like folly::detail::uintToBuffer in Conv.h, writes at the *end* of * the supplied buffer and returns the offset of the beginning of the string * from the start of the buffer. The formatted string will be in range * [buf+begin, buf+bufLen). */ template size_t uintToBinary(char* buffer, size_t bufLen, Uint v) { auto& repr = formatBinary; if (v == 0) { buffer[--bufLen] = '0'; return bufLen; } for (; v; v >>= 7, v >>= 1) { auto b = v & 0xff; bufLen -= 8; memcpy(buffer + bufLen, &(repr[b][0]), 8); } while (buffer[bufLen] == '0') { ++bufLen; } return bufLen; } } // namespace detail template BaseFormatter::BaseFormatter(StringPiece str, Args&&... args) : str_(str), values_(FormatValue::type>( std::forward(args))...) { static_assert(!containerMode || sizeof...(Args) == 1, "Exactly one argument required in container mode"); } template template void BaseFormatter::operator()(Output& out) const { // Copy raw string (without format specifiers) to output; // not as simple as we'd like, as we still need to translate "}}" to "}" // and throw if we see any lone "}" auto outputString = [&out] (StringPiece s) { auto p = s.begin(); auto end = s.end(); while (p != end) { auto q = static_cast(memchr(p, '}', end - p)); if (!q) { out(StringPiece(p, end)); break; } ++q; out(StringPiece(p, q)); p = q; if (p == end || *p != '}') { throw BadFormatArg("folly::format: single '}' in format string"); } ++p; } }; auto p = str_.begin(); auto end = str_.end(); int nextArg = 0; bool hasDefaultArgIndex = false; bool hasExplicitArgIndex = false; while (p != end) { auto q = static_cast(memchr(p, '{', end - p)); if (!q) { outputString(StringPiece(p, end)); break; } outputString(StringPiece(p, q)); p = q + 1; if (p == end) { throw BadFormatArg("folly::format: '}' at end of format string"); } // "{{" -> "{" if (*p == '{') { out(StringPiece(p, 1)); ++p; continue; } // Format string q = static_cast(memchr(p, '}', end - p)); if (q == nullptr) { throw BadFormatArg("folly::format: missing ending '}'"); } FormatArg arg(StringPiece(p, q)); p = q + 1; int argIndex = 0; auto piece = arg.splitKey(); // empty key component is okay if (containerMode) { // static arg.enforce(arg.width != FormatArg::kDynamicWidth, "dynamic field width not supported in vformat()"); if (piece.empty()) { arg.setNextIntKey(nextArg++); hasDefaultArgIndex = true; } else { arg.setNextKey(piece); hasExplicitArgIndex = true; } } else { if (piece.empty()) { if (arg.width == FormatArg::kDynamicWidth) { arg.enforce(arg.widthIndex == FormatArg::kNoIndex, "cannot provide width arg index without value arg index"); int sizeArg = nextArg++; arg.width = getSizeArg(sizeArg, arg); } argIndex = nextArg++; hasDefaultArgIndex = true; } else { if (arg.width == FormatArg::kDynamicWidth) { arg.enforce(arg.widthIndex != FormatArg::kNoIndex, "cannot provide value arg index without width arg index"); arg.width = getSizeArg(arg.widthIndex, arg); } try { argIndex = to(piece); } catch (const std::out_of_range& e) { arg.error("argument index must be integer"); } arg.enforce(argIndex >= 0, "argument index must be non-negative"); hasExplicitArgIndex = true; } } if (hasDefaultArgIndex && hasExplicitArgIndex) { throw BadFormatArg( "folly::format: may not have both default and explicit arg indexes"); } doFormat(argIndex, arg, out); } } template void writeTo(FILE* fp, const BaseFormatter& formatter) { auto writer = [fp] (StringPiece sp) { size_t n = fwrite(sp.data(), 1, sp.size(), fp); if (n < sp.size()) { throwSystemError("Formatter writeTo", "fwrite failed"); } }; formatter(writer); } namespace format_value { template void formatString(StringPiece val, FormatArg& arg, FormatCallback& cb) { if (arg.width != FormatArg::kDefaultWidth && arg.width < 0) { throw BadFormatArg("folly::format: invalid width"); } if (arg.precision != FormatArg::kDefaultPrecision && arg.precision < 0) { throw BadFormatArg("folly::format: invalid precision"); } // XXX: clang should be smart enough to not need the two static_cast // uses below given the above checks. If clang ever becomes that smart, we // should remove the otherwise unnecessary warts. if (arg.precision != FormatArg::kDefaultPrecision && val.size() > static_cast(arg.precision)) { val.reset(val.data(), arg.precision); } constexpr int padBufSize = 128; char padBuf[padBufSize]; // Output padding, no more than padBufSize at once auto pad = [&padBuf, &cb, padBufSize] (int chars) { while (chars) { int n = std::min(chars, padBufSize); cb(StringPiece(padBuf, n)); chars -= n; } }; int padRemaining = 0; if (arg.width != FormatArg::kDefaultWidth && val.size() < static_cast(arg.width)) { char fill = arg.fill == FormatArg::kDefaultFill ? ' ' : arg.fill; int padChars = static_cast (arg.width - val.size()); memset(padBuf, fill, std::min(padBufSize, padChars)); switch (arg.align) { case FormatArg::Align::DEFAULT: case FormatArg::Align::LEFT: padRemaining = padChars; break; case FormatArg::Align::CENTER: pad(padChars / 2); padRemaining = padChars - padChars / 2; break; case FormatArg::Align::RIGHT: case FormatArg::Align::PAD_AFTER_SIGN: pad(padChars); break; default: abort(); break; } } cb(val); if (padRemaining) { pad(padRemaining); } } template void formatNumber(StringPiece val, int prefixLen, FormatArg& arg, FormatCallback& cb) { // precision means something different for numbers arg.precision = FormatArg::kDefaultPrecision; if (arg.align == FormatArg::Align::DEFAULT) { arg.align = FormatArg::Align::RIGHT; } else if (prefixLen && arg.align == FormatArg::Align::PAD_AFTER_SIGN) { // Split off the prefix, then do any padding if necessary cb(val.subpiece(0, prefixLen)); val.advance(prefixLen); arg.width = std::max(arg.width - prefixLen, 0); } format_value::formatString(val, arg, cb); } template void formatFormatter( const BaseFormatter& formatter, FormatArg& arg, FormatCallback& cb) { if (arg.width == FormatArg::kDefaultWidth && arg.precision == FormatArg::kDefaultPrecision) { // nothing to do formatter(cb); } else if (arg.align != FormatArg::Align::LEFT && arg.align != FormatArg::Align::DEFAULT) { // We can only avoid creating a temporary string if we align left, // as we'd need to know the size beforehand otherwise format_value::formatString(formatter.fbstr(), arg, cb); } else { auto fn = [&arg, &cb] (StringPiece sp) mutable { int sz = static_cast(sp.size()); if (arg.precision != FormatArg::kDefaultPrecision) { sz = std::min(arg.precision, sz); sp.reset(sp.data(), sz); arg.precision -= sz; } if (!sp.empty()) { cb(sp); if (arg.width != FormatArg::kDefaultWidth) { arg.width = std::max(arg.width - sz, 0); } } }; formatter(fn); if (arg.width != FormatArg::kDefaultWidth && arg.width != 0) { // Rely on formatString to do appropriate padding format_value::formatString(StringPiece(), arg, cb); } } } } // namespace format_value // Definitions for default FormatValue classes // Integral types (except bool) template class FormatValue< T, typename std::enable_if< std::is_integral::value && !std::is_same::value>::type> { public: explicit FormatValue(T val) : val_(val) { } T getValue() const { return val_; } template void format(FormatArg& arg, FormatCallback& cb) const { arg.validate(FormatArg::Type::INTEGER); doFormat(arg, cb); } template void doFormat(FormatArg& arg, FormatCallback& cb) const { char presentation = arg.presentation; if (presentation == FormatArg::kDefaultPresentation) { presentation = std::is_same::value ? 'c' : 'd'; } // Do all work as unsigned, we'll add the prefix ('0' or '0x' if necessary) // and sign ourselves. typedef typename std::make_unsigned::type UT; UT uval; char sign; if (std::is_signed::value) { if (folly::is_negative(val_)) { uval = -static_cast(val_); sign = '-'; } else { uval = static_cast(val_); switch (arg.sign) { case FormatArg::Sign::PLUS_OR_MINUS: sign = '+'; break; case FormatArg::Sign::SPACE_OR_MINUS: sign = ' '; break; default: sign = '\0'; break; } } } else { uval = val_; sign = '\0'; arg.enforce(arg.sign == FormatArg::Sign::DEFAULT, "sign specifications not allowed for unsigned values"); } // max of: // #x: 0x prefix + 16 bytes = 18 bytes // #o: 0 prefix + 22 bytes = 23 bytes // #b: 0b prefix + 64 bytes = 65 bytes // ,d: 26 bytes (including thousands separators!) // + nul terminator // + 3 for sign and prefix shenanigans (see below) constexpr size_t valBufSize = 69; char valBuf[valBufSize]; char* valBufBegin = nullptr; char* valBufEnd = nullptr; int prefixLen = 0; switch (presentation) { case 'n': { arg.enforce(!arg.basePrefix, "base prefix not allowed with '", presentation, "' specifier"); arg.enforce(!arg.thousandsSeparator, "cannot use ',' with the '", presentation, "' specifier"); valBufBegin = valBuf + 3; // room for sign and base prefix #if defined(__ANDROID__) int len = snprintf(valBufBegin, (valBuf + valBufSize) - valBufBegin, "%" PRIuMAX, static_cast(uval)); #else int len = snprintf(valBufBegin, (valBuf + valBufSize) - valBufBegin, "%ju", static_cast(uval)); #endif // valBufSize should always be big enough, so this should never // happen. assert(len < valBuf + valBufSize - valBufBegin); valBufEnd = valBufBegin + len; break; } case 'd': arg.enforce(!arg.basePrefix, "base prefix not allowed with '", presentation, "' specifier"); valBufBegin = valBuf + 3; // room for sign and base prefix // Use uintToBuffer, faster than sprintf valBufEnd = valBufBegin + uint64ToBufferUnsafe(uval, valBufBegin); if (arg.thousandsSeparator) { detail::insertThousandsGroupingUnsafe(valBufBegin, &valBufEnd); } break; case 'c': arg.enforce(!arg.basePrefix, "base prefix not allowed with '", presentation, "' specifier"); arg.enforce(!arg.thousandsSeparator, "thousands separator (',') not allowed with '", presentation, "' specifier"); valBufBegin = valBuf + 3; *valBufBegin = static_cast(uval); valBufEnd = valBufBegin + 1; break; case 'o': case 'O': arg.enforce(!arg.thousandsSeparator, "thousands separator (',') not allowed with '", presentation, "' specifier"); valBufEnd = valBuf + valBufSize - 1; valBufBegin = valBuf + detail::uintToOctal(valBuf, valBufSize - 1, uval); if (arg.basePrefix) { *--valBufBegin = '0'; prefixLen = 1; } break; case 'x': arg.enforce(!arg.thousandsSeparator, "thousands separator (',') not allowed with '", presentation, "' specifier"); valBufEnd = valBuf + valBufSize - 1; valBufBegin = valBuf + detail::uintToHexLower(valBuf, valBufSize - 1, uval); if (arg.basePrefix) { *--valBufBegin = 'x'; *--valBufBegin = '0'; prefixLen = 2; } break; case 'X': arg.enforce(!arg.thousandsSeparator, "thousands separator (',') not allowed with '", presentation, "' specifier"); valBufEnd = valBuf + valBufSize - 1; valBufBegin = valBuf + detail::uintToHexUpper(valBuf, valBufSize - 1, uval); if (arg.basePrefix) { *--valBufBegin = 'X'; *--valBufBegin = '0'; prefixLen = 2; } break; case 'b': case 'B': arg.enforce(!arg.thousandsSeparator, "thousands separator (',') not allowed with '", presentation, "' specifier"); valBufEnd = valBuf + valBufSize - 1; valBufBegin = valBuf + detail::uintToBinary(valBuf, valBufSize - 1, uval); if (arg.basePrefix) { *--valBufBegin = presentation; // 0b or 0B *--valBufBegin = '0'; prefixLen = 2; } break; default: arg.error("invalid specifier '", presentation, "'"); } if (sign) { *--valBufBegin = sign; ++prefixLen; } format_value::formatNumber(StringPiece(valBufBegin, valBufEnd), prefixLen, arg, cb); } private: T val_; }; // Bool template <> class FormatValue { public: explicit FormatValue(bool val) : val_(val) { } template void format(FormatArg& arg, FormatCallback& cb) const { if (arg.presentation == FormatArg::kDefaultPresentation) { arg.validate(FormatArg::Type::OTHER); format_value::formatString(val_ ? "true" : "false", arg, cb); } else { // number FormatValue(val_).format(arg, cb); } } private: bool val_; }; // double template <> class FormatValue { public: explicit FormatValue(double val) : val_(val) { } template void format(FormatArg& arg, FormatCallback& cb) const { fbstring piece; int prefixLen; formatHelper(piece, prefixLen, arg); format_value::formatNumber(piece, prefixLen, arg, cb); } private: void formatHelper(fbstring& piece, int& prefixLen, FormatArg& arg) const; double val_; }; // float (defer to double) template <> class FormatValue { public: explicit FormatValue(float val) : val_(val) { } template void format(FormatArg& arg, FormatCallback& cb) const { FormatValue(val_).format(arg, cb); } private: float val_; }; // Sring-y types (implicitly convertible to StringPiece, except char*) template class FormatValue< T, typename std::enable_if< (!std::is_pointer::value || !std::is_same::type>::type>::value) && std::is_convertible::value>::type> { public: explicit FormatValue(StringPiece val) : val_(val) { } template void format(FormatArg& arg, FormatCallback& cb) const { if (arg.keyEmpty()) { arg.validate(FormatArg::Type::OTHER); arg.enforce(arg.presentation == FormatArg::kDefaultPresentation || arg.presentation == 's', "invalid specifier '", arg.presentation, "'"); format_value::formatString(val_, arg, cb); } else { FormatValue(val_.at(arg.splitIntKey())).format(arg, cb); } } private: StringPiece val_; }; // Null template <> class FormatValue { public: explicit FormatValue(std::nullptr_t) { } template void format(FormatArg& arg, FormatCallback& cb) const { arg.validate(FormatArg::Type::OTHER); arg.enforce(arg.presentation == FormatArg::kDefaultPresentation, "invalid specifier '", arg.presentation, "'"); format_value::formatString("(null)", arg, cb); } }; // Partial specialization of FormatValue for char* template class FormatValue< T*, typename std::enable_if< std::is_same::type>::value>::type> { public: explicit FormatValue(T* val) : val_(val) { } template void format(FormatArg& arg, FormatCallback& cb) const { if (arg.keyEmpty()) { if (!val_) { FormatValue(nullptr).format(arg, cb); } else { FormatValue(val_).format(arg, cb); } } else { FormatValue::type>( val_[arg.splitIntKey()]).format(arg, cb); } } private: T* val_; }; // Partial specialization of FormatValue for void* template class FormatValue< T*, typename std::enable_if< std::is_same::type>::value>::type> { public: explicit FormatValue(T* val) : val_(val) { } template void format(FormatArg& arg, FormatCallback& cb) const { if (!val_) { FormatValue(nullptr).format(arg, cb); } else { // Print as a pointer, in hex. arg.validate(FormatArg::Type::OTHER); arg.enforce(arg.presentation == FormatArg::kDefaultPresentation, "invalid specifier '", arg.presentation, "'"); arg.basePrefix = true; arg.presentation = 'x'; if (arg.align == FormatArg::Align::DEFAULT) { arg.align = FormatArg::Align::LEFT; } FormatValue( reinterpret_cast(val_)).doFormat(arg, cb); } } private: T* val_; }; template class TryFormatValue { public: template static void formatOrFail(T& /* value */, FormatArg& arg, FormatCallback& /* cb */) { arg.error("No formatter available for this type"); } }; template class TryFormatValue< T, typename std::enable_if< 0 < sizeof(FormatValue::type>)>::type> { public: template static void formatOrFail(T& value, FormatArg& arg, FormatCallback& cb) { FormatValue::type>(value).format(arg, cb); } }; // Partial specialization of FormatValue for other pointers template class FormatValue< T*, typename std::enable_if< !std::is_same::type>::value && !std::is_same::type>::value>::type> { public: explicit FormatValue(T* val) : val_(val) { } template void format(FormatArg& arg, FormatCallback& cb) const { if (arg.keyEmpty()) { FormatValue((void*)val_).format(arg, cb); } else { TryFormatValue::formatOrFail(val_[arg.splitIntKey()], arg, cb); } } private: T* val_; }; namespace detail { // std::array template struct IndexableTraits> : public IndexableTraitsSeq> { }; // std::vector template struct IndexableTraits> : public IndexableTraitsSeq> { }; // std::deque template struct IndexableTraits> : public IndexableTraitsSeq> { }; // std::map with integral keys template struct IndexableTraits< std::map, typename std::enable_if::value>::type> : public IndexableTraitsAssoc> { }; // std::unordered_map with integral keys template struct IndexableTraits< std::unordered_map, typename std::enable_if::value>::type> : public IndexableTraitsAssoc> { }; } // namespace detail // Partial specialization of FormatValue for integer-indexable containers template class FormatValue< T, typename detail::IndexableTraits::enabled> { public: explicit FormatValue(const T& val) : val_(val) { } template void format(FormatArg& arg, FormatCallback& cb) const { FormatValue::value_type>::type>( detail::IndexableTraits::at( val_, arg.splitIntKey())).format(arg, cb); } private: const T& val_; }; template class FormatValue< detail::DefaultValueWrapper, typename detail::IndexableTraits::enabled> { public: explicit FormatValue(const detail::DefaultValueWrapper& val) : val_(val) { } template void format(FormatArg& arg, FormatCallback& cb) const { FormatValue::value_type>::type>( detail::IndexableTraits::at( val_.container, arg.splitIntKey(), val_.defaultValue)).format(arg, cb); } private: const detail::DefaultValueWrapper& val_; }; namespace detail { // Define enabled, key_type, convert from StringPiece to the key types // that we support template struct KeyFromStringPiece; // std::string template <> struct KeyFromStringPiece : public FormatTraitsBase { typedef std::string key_type; static std::string convert(StringPiece s) { return s.toString(); } typedef void enabled; }; // fbstring template <> struct KeyFromStringPiece : public FormatTraitsBase { typedef fbstring key_type; static fbstring convert(StringPiece s) { return s.toFbstring(); } }; // StringPiece template <> struct KeyFromStringPiece : public FormatTraitsBase { typedef StringPiece key_type; static StringPiece convert(StringPiece s) { return s; } }; // Base class for associative types keyed by strings template struct KeyableTraitsAssoc : public FormatTraitsBase { typedef typename T::key_type key_type; typedef typename T::value_type::second_type value_type; static const value_type& at(const T& map, StringPiece key) { return map.at(KeyFromStringPiece::convert(key)); } static const value_type& at(const T& map, StringPiece key, const value_type& dflt) { auto pos = map.find(KeyFromStringPiece::convert(key)); return pos != map.end() ? pos->second : dflt; } }; // Define enabled, key_type, value_type, at() for supported string-keyed // types template struct KeyableTraits; // std::map with string key template struct KeyableTraits< std::map, typename KeyFromStringPiece::enabled> : public KeyableTraitsAssoc> { }; // std::unordered_map with string key template struct KeyableTraits< std::unordered_map, typename KeyFromStringPiece::enabled> : public KeyableTraitsAssoc> { }; } // namespace detail // Partial specialization of FormatValue for string-keyed containers template class FormatValue< T, typename detail::KeyableTraits::enabled> { public: explicit FormatValue(const T& val) : val_(val) { } template void format(FormatArg& arg, FormatCallback& cb) const { FormatValue::value_type>::type>( detail::KeyableTraits::at( val_, arg.splitKey())).format(arg, cb); } private: const T& val_; }; template class FormatValue< detail::DefaultValueWrapper, typename detail::KeyableTraits::enabled> { public: explicit FormatValue(const detail::DefaultValueWrapper& val) : val_(val) { } template void format(FormatArg& arg, FormatCallback& cb) const { FormatValue::value_type>::type>( detail::KeyableTraits::at( val_.container, arg.splitKey(), val_.defaultValue)).format(arg, cb); } private: const detail::DefaultValueWrapper& val_; }; // Partial specialization of FormatValue for pairs template class FormatValue> { public: explicit FormatValue(const std::pair& val) : val_(val) { } template void format(FormatArg& arg, FormatCallback& cb) const { int key = arg.splitIntKey(); switch (key) { case 0: FormatValue::type>(val_.first).format(arg, cb); break; case 1: FormatValue::type>(val_.second).format(arg, cb); break; default: arg.error("invalid index for pair"); } } private: const std::pair& val_; }; // Partial specialization of FormatValue for tuples template class FormatValue> { typedef std::tuple Tuple; public: explicit FormatValue(const Tuple& val) : val_(val) { } template void format(FormatArg& arg, FormatCallback& cb) const { int key = arg.splitIntKey(); arg.enforce(key >= 0, "tuple index must be non-negative"); doFormat(key, arg, cb); } private: static constexpr size_t valueCount = std::tuple_size::value; template typename std::enable_if::type doFormatFrom( size_t i, FormatArg& arg, Callback& /* cb */) const { arg.enforce("tuple index out of range, max=", i); } template typename std::enable_if<(K < valueCount)>::type doFormatFrom(size_t i, FormatArg& arg, Callback& cb) const { if (i == K) { FormatValue::type>::type>( std::get(val_)).format(arg, cb); } else { doFormatFrom(i, arg, cb); } } template void doFormat(size_t i, FormatArg& arg, Callback& cb) const { return doFormatFrom<0>(i, arg, cb); } const Tuple& val_; }; // Partial specialization of FormatValue for nested Formatters template class F> class FormatValue, typename std::enable_if>::value>::type> { typedef typename F::BaseType FormatterValue; public: explicit FormatValue(const FormatterValue& f) : f_(f) { } template void format(FormatArg& arg, FormatCallback& cb) const { format_value::formatFormatter(f_, arg, cb); } private: const FormatterValue& f_; }; /** * Formatter objects can be appended to strings, and therefore they're * compatible with folly::toAppend and folly::to. */ template typename std::enable_if::value>::type toAppend( const BaseFormatter& value, Tgt* result) { value.appendTo(*result); } } // namespace folly #pragma GCC diagnostic pop