/*
- * Copyright 2014 Facebook, Inc.
+ * Copyright 2015 Facebook, Inc.
*
* Licensed under the Apache License, Version 2.0 (the "License");
* you may not use this file except in compliance with the License.
// either before or after this inclusion.
#ifdef FOLLY_MALLOC_H_
#undef FOLLY_MALLOC_H_
-#include "basic_fbstring_malloc.h"
+#include "basic_fbstring_malloc.h" // nolint
#else
-#include "basic_fbstring_malloc.h"
+#include "basic_fbstring_malloc.h" // nolint
#undef FOLLY_MALLOC_H_
#endif
// FBString cannot use throw when replacing std::string, though it may still
// use std::__throw_*
+// nolint
#define throw FOLLY_FBSTRING_MAY_NOT_USE_THROW
#ifdef _LIBSTDCXX_FBSTRING
// has issues when inlining is used, so disable that as well.
#if defined(__clang__)
# if __has_feature(address_sanitizer)
-# if __has_attribute(__no_address_safety_analysis__)
+# if __has_attribute(__no_sanitize__)
+# define FBSTRING_DISABLE_ADDRESS_SANITIZER \
+ __attribute__((__no_sanitize__("address"), __noinline__))
+# elif __has_attribute(__no_address_safety_analysis__)
# define FBSTRING_DISABLE_ADDRESS_SANITIZER \
__attribute__((__no_address_safety_analysis__, __noinline__))
# elif __has_attribute(__no_sanitize_address__)
};
*/
-/**
- * gcc-4.7 throws what appears to be some false positive uninitialized
- * warnings for the members of the MediumLarge struct. So, mute them here.
- */
-#if defined(__GNUC__) && !defined(__clang__)
-# pragma GCC diagnostic push
-# pragma GCC diagnostic ignored "-Wuninitialized"
-#endif
-
/**
* This is the core of the string. The code should work on 32- and
- * 64-bit architectures and with any Char size. Porting to big endian
- * architectures would require some changes.
+ * 64-bit and both big- and little-endianan architectures with any
+ * Char size.
*
* The storage is selected as follows (assuming we store one-byte
* characters on a 64-bit machine): (a) "small" strings between 0 and
* reference-counted and copied lazily. the reference count is
* allocated right before the character array.
*
- * The discriminator between these three strategies sits in the two
- * most significant bits of the rightmost char of the storage. If
- * neither is set, then the string is small (and its length sits in
- * the lower-order bits of that rightmost character). If the MSb is
- * set, the string is medium width. If the second MSb is set, then the
- * string is large.
+ * The discriminator between these three strategies sits in two
+ * bits of the rightmost char of the storage. If neither is set, then the
+ * string is small (and its length sits in the lower-order bits on
+ * little-endian or the high-order bits on big-endian of that
+ * rightmost character). If the MSb is set, the string is medium width.
+ * If the second MSb is set, then the string is large. On little-endian,
+ * these 2 bits are the 2 MSbs of MediumLarge::capacity_, while on
+ * big-endian, these 2 bits are the 2 LSbs. This keeps both little-endian
+ * and big-endian fbstring_core equivalent with merely different ops used
+ * to extract capacity/category.
*/
template <class Char> class fbstring_core {
+protected:
+ static constexpr bool kIsLittleEndian =
+ __BYTE_ORDER__ == __ORDER_LITTLE_ENDIAN__;
+ static constexpr bool kIsBigEndian =
+ __BYTE_ORDER__ == __ORDER_BIG_ENDIAN__;
+ static_assert(
+ kIsLittleEndian || kIsBigEndian, "unable to identify endianness");
public:
- fbstring_core() noexcept {
- // Only initialize the tag, will set the MSBs (i.e. the small
- // string size) to zero too
- ml_.capacity_ = maxSmallSize << (8 * (sizeof(size_t) - sizeof(Char)));
- // or: setSmallSize(0);
- writeTerminator();
- assert(category() == isSmall && size() == 0);
- }
+ fbstring_core() noexcept { reset(); }
fbstring_core(const fbstring_core & rhs) {
assert(&rhs != this);
// Simplest case first: small strings are bitblitted
- if (rhs.category() == isSmall) {
+ if (rhs.category() == Category::isSmall) {
static_assert(offsetof(MediumLarge, data_) == 0,
"fbstring layout failure");
static_assert(offsetof(MediumLarge, size_) == sizeof(ml_.data_),
"fbstring layout failure");
static_assert(offsetof(MediumLarge, capacity_) == 2 * sizeof(ml_.data_),
"fbstring layout failure");
- const size_t size = rhs.smallSize();
- if (size == 0) {
- ml_.capacity_ = rhs.ml_.capacity_;
- writeTerminator();
- } else {
- // Just write the whole thing, don't look at details. In
- // particular we need to copy capacity anyway because we want
- // to set the size (don't forget that the last character,
- // which stores a short string's length, is shared with the
- // ml_.capacity field).
- ml_ = rhs.ml_;
- }
- assert(category() == isSmall && this->size() == rhs.size());
- } else if (rhs.category() == isLarge) {
+ // Just write the whole thing, don't look at details. In
+ // particular we need to copy capacity anyway because we want
+ // to set the size (don't forget that the last character,
+ // which stores a short string's length, is shared with the
+ // ml_.capacity field).
+ ml_ = rhs.ml_;
+ assert(category() == Category::isSmall && this->size() == rhs.size());
+ } else if (rhs.category() == Category::isLarge) {
// Large strings are just refcounted
ml_ = rhs.ml_;
RefCounted::incrementRefs(ml_.data_);
- assert(category() == isLarge && size() == rhs.size());
+ assert(category() == Category::isLarge && size() == rhs.size());
} else {
// Medium strings are copied eagerly. Don't forget to allocate
// one extra Char for the null terminator.
// No need for writeTerminator() here, we copied one extra
// element just above.
ml_.size_ = rhs.ml_.size_;
- ml_.capacity_ = (allocSize / sizeof(Char) - 1) | isMedium;
- assert(category() == isMedium);
+ ml_.setCapacity(allocSize / sizeof(Char) - 1, Category::isMedium);
+ assert(category() == Category::isMedium);
}
assert(size() == rhs.size());
assert(memcmp(data(), rhs.data(), size() * sizeof(Char)) == 0);
}
fbstring_core(fbstring_core&& goner) noexcept {
- if (goner.category() == isSmall) {
- // Just copy, leave the goner in peace
- new(this) fbstring_core(goner.small_, goner.smallSize());
- } else {
- // Take goner's guts
- ml_ = goner.ml_;
+ // Take goner's guts
+ ml_ = goner.ml_;
+ if (goner.category() != Category::isSmall) {
// Clean goner's carcass
- goner.setSmallSize(0);
+ goner.reset();
}
}
ml_.data_ = static_cast<Char*>(checkedMalloc(allocSize));
fbstring_detail::pod_copy(data, data + size, ml_.data_);
ml_.size_ = size;
- ml_.capacity_ = (allocSize / sizeof(Char) - 1) | isMedium;
+ ml_.setCapacity(allocSize / sizeof(Char) - 1, Category::isMedium);
} else {
// Large strings are allocated differently
size_t effectiveCapacity = size;
auto const newRC = RefCounted::create(data, & effectiveCapacity);
ml_.data_ = newRC->data_;
ml_.size_ = size;
- ml_.capacity_ = effectiveCapacity | isLarge;
+ ml_.setCapacity(effectiveCapacity, Category::isLarge);
}
writeTerminator();
}
~fbstring_core() noexcept {
auto const c = category();
- if (c == isSmall) {
+ if (c == Category::isSmall) {
return;
}
- if (c == isMedium) {
+ if (c == Category::isMedium) {
free(ml_.data_);
return;
}
ml_.data_ = data;
ml_.size_ = size;
// Don't forget about null terminator
- ml_.capacity_ = (allocatedSize - 1) | isMedium;
+ ml_.setCapacity(allocatedSize - 1, Category::isMedium);
} else {
// No need for the memory
free(data);
- setSmallSize(0);
+ reset();
}
}
Char * mutable_data() {
auto const c = category();
- if (c == isSmall) {
+ if (c == Category::isSmall) {
return small_;
}
- assert(c == isMedium || c == isLarge);
- if (c == isLarge && RefCounted::refs(ml_.data_) > 1) {
+ assert(c == Category::isMedium || c == Category::isLarge);
+ if (c == Category::isLarge && RefCounted::refs(ml_.data_) > 1) {
// Ensure unique.
size_t effectiveCapacity = ml_.capacity();
auto const newRC = RefCounted::create(& effectiveCapacity);
const Char * c_str() const {
auto const c = category();
- if (c == isSmall) {
+ if (c == Category::isSmall) {
assert(small_[smallSize()] == '\0');
return small_;
}
- assert(c == isMedium || c == isLarge);
+ assert(c == Category::isMedium || c == Category::isLarge);
assert(ml_.data_[ml_.size_] == '\0');
return ml_.data_;
}
void shrink(const size_t delta) {
- if (category() == isSmall) {
+ if (category() == Category::isSmall) {
// Check for underflow
assert(delta <= smallSize());
setSmallSize(smallSize() - delta);
- } else if (category() == isMedium || RefCounted::refs(ml_.data_) == 1) {
+ } else if (category() == Category::isMedium ||
+ RefCounted::refs(ml_.data_) == 1) {
// Medium strings and unique large strings need no special
// handling.
assert(ml_.size_ >= delta);
}
void reserve(size_t minCapacity) {
- if (category() == isLarge) {
+ if (category() == Category::isLarge) {
// Ensure unique
if (RefCounted::refs(ml_.data_) > 1) {
// We must make it unique regardless; in-place reallocation is
// we have + 1 above.
RefCounted::decrementRefs(ml_.data_);
ml_.data_ = newRC->data_;
- ml_.capacity_ = minCapacity | isLarge;
+ ml_.setCapacity(minCapacity, Category::isLarge);
// size remains unchanged
} else {
// String is not shared, so let's try to realloc (if needed)
RefCounted::reallocate(ml_.data_, ml_.size_,
ml_.capacity(), minCapacity);
ml_.data_ = newRC->data_;
- ml_.capacity_ = minCapacity | isLarge;
+ ml_.setCapacity(minCapacity, Category::isLarge);
writeTerminator();
}
assert(capacity() >= minCapacity);
}
- } else if (category() == isMedium) {
+ } else if (category() == Category::isMedium) {
// String is not shared
if (minCapacity <= ml_.capacity()) {
return; // nothing to do, there's enough room
(ml_.capacity() + 1) * sizeof(Char),
capacityBytes));
writeTerminator();
- ml_.capacity_ = (capacityBytes / sizeof(Char) - 1) | isMedium;
+ ml_.setCapacity(capacityBytes / sizeof(Char) - 1, Category::isMedium);
} else {
// Conversion from medium to large string
fbstring_core nascent;
assert(capacity() >= minCapacity);
}
} else {
- assert(category() == isSmall);
+ assert(category() == Category::isSmall);
if (minCapacity > maxMediumSize) {
// large
auto const newRC = RefCounted::create(& minCapacity);
// No need for writeTerminator(), we wrote it above with + 1.
ml_.data_ = newRC->data_;
ml_.size_ = size;
- ml_.capacity_ = minCapacity | isLarge;
+ ml_.setCapacity(minCapacity, Category::isLarge);
assert(capacity() >= minCapacity);
} else if (minCapacity > maxSmallSize) {
// medium
// No need for writeTerminator(), we wrote it above with + 1.
ml_.data_ = data;
ml_.size_ = size;
- ml_.capacity_ = (allocSizeBytes / sizeof(Char) - 1) | isMedium;
+ ml_.setCapacity(allocSizeBytes / sizeof(Char) - 1, Category::isMedium);
} else {
// small
// Nothing to do, everything stays put
// Strategy is simple: make room, then change size
assert(capacity() >= size());
size_t sz, newSz;
- if (category() == isSmall) {
+ if (category() == Category::isSmall) {
sz = smallSize();
newSz = sz + delta;
if (newSz <= maxSmallSize) {
}
assert(capacity() >= newSz);
// Category can't be small - we took care of that above
- assert(category() == isMedium || category() == isLarge);
+ assert(category() == Category::isMedium || category() == Category::isLarge);
ml_.size_ = newSz;
writeTerminator();
assert(size() == newSz);
void push_back(Char c) {
assert(capacity() >= size());
size_t sz;
- if (category() == isSmall) {
+ if (category() == Category::isSmall) {
sz = smallSize();
if (sz < maxSmallSize) {
small_[sz] = c;
assert(!isShared());
assert(capacity() >= sz + 1);
// Category can't be small - we took care of that above
- assert(category() == isMedium || category() == isLarge);
+ assert(category() == Category::isMedium || category() == Category::isLarge);
ml_.size_ = sz + 1;
ml_.data_[sz] = c;
writeTerminator();
}
size_t size() const {
- return category() == isSmall ? smallSize() : ml_.size_;
+ return category() == Category::isSmall ? smallSize() : ml_.size_;
}
size_t capacity() const {
switch (category()) {
- case isSmall:
+ case Category::isSmall:
return maxSmallSize;
- case isLarge:
+ case Category::isLarge:
// For large-sized strings, a multi-referenced chunk has no
// available capacity. This is because any attempt to append
// data would trigger a new allocation.
}
bool isShared() const {
- return category() == isLarge && RefCounted::refs(ml_.data_) > 1;
+ return category() == Category::isLarge && RefCounted::refs(ml_.data_) > 1;
}
void writeTerminator() {
- if (category() == isSmall) {
+ if (category() == Category::isSmall) {
const auto s = smallSize();
if (s != maxSmallSize) {
small_[s] = '\0';
// Disabled
fbstring_core & operator=(const fbstring_core & rhs);
- struct MediumLarge {
- Char * data_;
- size_t size_;
- size_t capacity_;
-
- size_t capacity() const {
- return capacity_ & capacityExtractMask;
- }
- };
+ // Equivalent to setSmallSize(0), but with specialized
+ // writeTerminator which doesn't re-check the category after
+ // capacity_ is overwritten.
+ void reset() {
+ // Only initialize the tag, will set the MSBs (i.e. the small
+ // string size) to zero too.
+ ml_.capacity_ = kIsLittleEndian
+ ? maxSmallSize << (8 * (sizeof(size_t) - sizeof(Char)))
+ : maxSmallSize << 2;
+ small_[0] = '\0';
+ assert(category() == Category::isSmall && size() == 0);
+ }
struct RefCounted {
std::atomic<size_t> refCount_;
}
};
+ typedef std::conditional<sizeof(size_t) == 4, uint32_t, uint64_t>::type
+ category_type;
+
+ enum class Category : category_type {
+ isSmall = 0,
+ isMedium = kIsLittleEndian
+ ? sizeof(size_t) == 4 ? 0x80000000 : 0x8000000000000000
+ : 0x2,
+ isLarge = kIsLittleEndian
+ ? sizeof(size_t) == 4 ? 0x40000000 : 0x4000000000000000
+ : 0x1,
+ };
+
+ Category category() const {
+ // works for both big-endian and little-endian
+ return static_cast<Category>(ml_.capacity_ & categoryExtractMask);
+ }
+
+ struct MediumLarge {
+ Char * data_;
+ size_t size_;
+ size_t capacity_;
+
+ size_t capacity() const {
+ return kIsLittleEndian
+ ? capacity_ & capacityExtractMask
+ : capacity_ >> 2;
+ }
+
+ void setCapacity(size_t cap, Category cat) {
+ capacity_ = kIsLittleEndian
+ ? cap | static_cast<category_type>(cat)
+ : (cap << 2) | static_cast<category_type>(cat);
+ }
+ };
+
union {
Char small_[sizeof(MediumLarge) / sizeof(Char)];
MediumLarge ml_;
};
- enum {
+ enum : size_t {
lastChar = sizeof(MediumLarge) - 1,
maxSmallSize = lastChar / sizeof(Char),
maxMediumSize = 254 / sizeof(Char), // coincides with the small
// bin size in dlmalloc
- categoryExtractMask = sizeof(size_t) == 4 ? 0xC0000000 : 0xC000000000000000,
- capacityExtractMask = ~categoryExtractMask,
+ categoryExtractMask = kIsLittleEndian
+ ? sizeof(size_t) == 4 ? 0xC0000000 : 0xC000000000000000
+ : 0x3,
+ capacityExtractMask = kIsLittleEndian
+ ? ~categoryExtractMask
+ : 0x0 /*unused*/,
};
static_assert(!(sizeof(MediumLarge) % sizeof(Char)),
"Corrupt memory layout for fbstring.");
- enum Category {
- isSmall = 0,
- isMedium = sizeof(size_t) == 4 ? 0x80000000 : 0x8000000000000000,
- isLarge = sizeof(size_t) == 4 ? 0x40000000 : 0x4000000000000000,
- };
-
- Category category() const {
- // Assumes little endian
- return static_cast<Category>(ml_.capacity_ & categoryExtractMask);
- }
-
size_t smallSize() const {
- assert(category() == isSmall &&
- static_cast<size_t>(small_[maxSmallSize])
- <= static_cast<size_t>(maxSmallSize));
- return static_cast<size_t>(maxSmallSize)
- - static_cast<size_t>(small_[maxSmallSize]);
+ assert(category() == Category::isSmall);
+ auto shift = kIsLittleEndian ? 0 : 2;
+ auto smallShifted = static_cast<size_t>(small_[maxSmallSize]) >> shift;
+ assert(static_cast<size_t>(maxSmallSize) >= smallShifted);
+ return static_cast<size_t>(maxSmallSize) - smallShifted;
}
void setSmallSize(size_t s) {
// so don't assume anything about the previous value of
// small_[maxSmallSize].
assert(s <= maxSmallSize);
- small_[maxSmallSize] = maxSmallSize - s;
+ small_[maxSmallSize] = kIsLittleEndian
+ ? maxSmallSize - s
+ : (maxSmallSize - s) << 2;
writeTerminator();
}
};
-#if defined(__GNUC__) && !defined(__clang__)
-# pragma GCC diagnostic pop
-#endif
-
#ifndef _LIBSTDCXX_FBSTRING
/**
* Dummy fbstring core that uses an actual std::string. This doesn't
public:
// C++11 21.4.2 construct/copy/destroy
- explicit basic_fbstring(const A& a = A()) noexcept {
+ explicit basic_fbstring(const A& /*a*/ = A()) noexcept {
}
basic_fbstring(const basic_fbstring& str)
assign(str, pos, n);
}
- /* implicit */ basic_fbstring(const value_type* s, const A& a = A())
+ /* implicit */ basic_fbstring(const value_type* s, const A& /*a*/ = A())
: store_(s, s
? traits_type::length(s)
: (std::__throw_logic_error(
0)) {
}
- basic_fbstring(const value_type* s, size_type n, const A& a = A())
+ basic_fbstring(const value_type* s, size_type n, const A& /*a*/ = A())
: store_(s, n) {
}
- basic_fbstring(size_type n, value_type c, const A& a = A()) {
+ basic_fbstring(size_type n, value_type c, const A& /*a*/ = A()) {
auto const data = store_.expand_noinit(n);
fbstring_detail::pod_fill(data, data + n, c);
store_.writeTerminator();
basic_fbstring(InIt begin, InIt end,
typename std::enable_if<
!std::is_same<typename std::remove_const<InIt>::type,
- value_type*>::value, const A>::type & a = A()) {
+ value_type*>::value, const A>::type & /*a*/ = A()) {
assign(begin, end);
}
return find_last_not_of(&c, pos, 1);
}
- basic_fbstring substr(size_type pos = 0, size_type n = npos) const {
+ basic_fbstring substr(size_type pos = 0, size_type n = npos) const& {
enforce(pos <= size(), std::__throw_out_of_range, "");
return basic_fbstring(data() + pos, std::min(n, size() - pos));
}
+ basic_fbstring substr(size_type pos = 0, size_type n = npos) && {
+ enforce(pos <= size(), std::__throw_out_of_range, "");
+ erase(0, pos);
+ if (n < size()) resize(n);
+ return std::move(*this);
+ }
+
int compare(const basic_fbstring& str) const {
// FIX due to Goncalo N M de Carvalho July 18, 2005
return compare(0, size(), str);
};
// non-member functions
-// C++11 21.4.8.1/2
+// C++11 21.4.8.1/1
template <typename E, class T, class A, class S>
inline
basic_fbstring<E, T, A, S> operator+(const basic_fbstring<E, T, A, S>& lhs,
return std::move(lhs.append(rhs));
}
+// C++11 21.4.8.1/5
template <typename E, class T, class A, class S>
inline
basic_fbstring<E, T, A, S> operator+(
- const typename basic_fbstring<E, T, A, S>::value_type* lhs,
+ const E* lhs,
const basic_fbstring<E, T, A, S>& rhs) {
//
basic_fbstring<E, T, A, S> result;
- const typename basic_fbstring<E, T, A, S>::size_type len =
- basic_fbstring<E, T, A, S>::traits_type::length(lhs);
+ const auto len = basic_fbstring<E, T, A, S>::traits_type::length(lhs);
result.reserve(len + rhs.size());
result.append(lhs, len).append(rhs);
return result;
}
+// C++11 21.4.8.1/6
template <typename E, class T, class A, class S>
inline
basic_fbstring<E, T, A, S> operator+(
- typename basic_fbstring<E, T, A, S>::value_type lhs,
+ const E* lhs,
+ basic_fbstring<E, T, A, S>&& rhs) {
+ //
+ const auto len = basic_fbstring<E, T, A, S>::traits_type::length(lhs);
+ if (rhs.capacity() >= len + rhs.size()) {
+ // Good, at least we don't need to reallocate
+ return std::move(rhs.insert(rhs.begin(), lhs, lhs + len));
+ }
+ // Meh, no go. Do it by hand since we have len already.
+ basic_fbstring<E, T, A, S> result;
+ result.reserve(len + rhs.size());
+ result.append(lhs, len).append(rhs);
+ return result;
+}
+
+// C++11 21.4.8.1/7
+template <typename E, class T, class A, class S>
+inline
+basic_fbstring<E, T, A, S> operator+(
+ E lhs,
const basic_fbstring<E, T, A, S>& rhs) {
basic_fbstring<E, T, A, S> result;
return result;
}
+// C++11 21.4.8.1/8
+template <typename E, class T, class A, class S>
+inline
+basic_fbstring<E, T, A, S> operator+(
+ E lhs,
+ basic_fbstring<E, T, A, S>&& rhs) {
+ //
+ if (rhs.capacity() > rhs.size()) {
+ // Good, at least we don't need to reallocate
+ return std::move(rhs.insert(rhs.begin(), lhs));
+ }
+ // Meh, no go. Forward to operator+(E, const&).
+ auto const& rhsC = rhs;
+ return lhs + rhsC;
+}
+
+// C++11 21.4.8.1/9
template <typename E, class T, class A, class S>
inline
basic_fbstring<E, T, A, S> operator+(
const basic_fbstring<E, T, A, S>& lhs,
- const typename basic_fbstring<E, T, A, S>::value_type* rhs) {
+ const E* rhs) {
typedef typename basic_fbstring<E, T, A, S>::size_type size_type;
typedef typename basic_fbstring<E, T, A, S>::traits_type traits_type;
return result;
}
+// C++11 21.4.8.1/10
+template <typename E, class T, class A, class S>
+inline
+basic_fbstring<E, T, A, S> operator+(
+ basic_fbstring<E, T, A, S>&& lhs,
+ const E* rhs) {
+ //
+ return std::move(lhs += rhs);
+}
+
+// C++11 21.4.8.1/11
template <typename E, class T, class A, class S>
inline
basic_fbstring<E, T, A, S> operator+(
const basic_fbstring<E, T, A, S>& lhs,
- typename basic_fbstring<E, T, A, S>::value_type rhs) {
+ E rhs) {
basic_fbstring<E, T, A, S> result;
result.reserve(lhs.size() + 1);
return result;
}
+// C++11 21.4.8.1/12
+template <typename E, class T, class A, class S>
+inline
+basic_fbstring<E, T, A, S> operator+(
+ basic_fbstring<E, T, A, S>&& lhs,
+ E rhs) {
+ //
+ return std::move(lhs += rhs);
+}
+
template <typename E, class T, class A, class S>
inline
bool operator==(const basic_fbstring<E, T, A, S>& lhs,
auto err = __ios_base::goodbit;
if (sentry) {
auto n = is.width();
- if (n == 0) {
+ if (n <= 0) {
n = str.max_size();
}
str.erase();
- auto got = is.rdbuf()->sgetc();
- for (; extracted != n && got != T::eof() && !isspace(got); ++extracted) {
- // Whew. We get to store this guy
+ for (auto got = is.rdbuf()->sgetc(); extracted != size_t(n); ++extracted) {
+ if (got == T::eof()) {
+ err |= __ios_base::eofbit;
+ is.width(0);
+ break;
+ }
+ if (isspace(got)) break;
str.push_back(got);
got = is.rdbuf()->snextc();
}
- if (got == T::eof()) {
- err |= __ios_base::eofbit;
- is.width(0);
- }
}
if (!extracted) {
err |= __ios_base::failbit;
os.setstate(std::ios_base::badbit | std::ios_base::failbit);
}
}
+#elif defined(_MSC_VER)
+ // MSVC doesn't define __ostream_insert
+ os.write(str.data(), str.size());
#else
std::__ostream_insert(os, str.data(), str.size());
#endif
//
// Handle interaction with different C++ standard libraries, which
// expect these types to be in different namespaces.
-namespace std {
-template <class C>
-struct hash<folly::basic_fbstring<C> > : private hash<const C*> {
- size_t operator()(const folly::basic_fbstring<C> & s) const {
- return hash<const C*>::operator()(s.c_str());
- }
-};
+#define FOLLY_FBSTRING_HASH1(T) \
+ template <> \
+ struct hash< ::folly::basic_fbstring<T> > { \
+ size_t operator()(const ::folly::fbstring& s) const { \
+ return ::folly::hash::fnv32_buf(s.data(), s.size()); \
+ } \
+ };
-template <>
-struct hash< ::folly::fbstring> {
- size_t operator()(const ::folly::fbstring& s) const {
- return ::folly::hash::fnv32_buf(s.data(), s.size());
- }
-};
+// The C++11 standard says that these four are defined
+#define FOLLY_FBSTRING_HASH \
+ FOLLY_FBSTRING_HASH1(char) \
+ FOLLY_FBSTRING_HASH1(char16_t) \
+ FOLLY_FBSTRING_HASH1(char32_t) \
+ FOLLY_FBSTRING_HASH1(wchar_t)
-}
+namespace std {
+
+FOLLY_FBSTRING_HASH
+
+} // namespace std
-#ifndef _LIBSTDCXX_FBSTRING
#if FOLLY_HAVE_DEPRECATED_ASSOC
#if defined(_GLIBCXX_SYMVER) && !defined(__BIONIC__)
namespace __gnu_cxx {
-template <class C>
-struct hash<folly::basic_fbstring<C> > : private hash<const C*> {
- size_t operator()(const folly::basic_fbstring<C> & s) const {
- return hash<const C*>::operator()(s.c_str());
- }
-};
+FOLLY_FBSTRING_HASH
-template <>
-struct hash< ::folly::fbstring> {
- size_t operator()(const ::folly::fbstring& s) const {
- return ::folly::hash::fnv32_buf(s.data(), s.size());
- }
-};
-
-}
+} // namespace __gnu_cxx
#endif // _GLIBCXX_SYMVER && !__BIONIC__
#endif // FOLLY_HAVE_DEPRECATED_ASSOC
-#endif // _LIBSTDCXX_FBSTRING
+
+#undef FOLLY_FBSTRING_HASH
+#undef FOLLY_FBSTRING_HASH1
#endif // _LIBSTDCXX_FBSTRING