*/
template <class Pod>
inline void podCopy(const Pod* b, const Pod* e, Pod* d) {
+ FBSTRING_ASSERT(b != nullptr);
+ FBSTRING_ASSERT(e != nullptr);
+ FBSTRING_ASSERT(d != nullptr);
FBSTRING_ASSERT(e >= b);
FBSTRING_ASSERT(d >= e || d + (e - b) <= b);
memcpy(d, b, (e - b) * sizeof(Pod));
}
~fbstring_core() noexcept {
- auto const c = category();
- if (c == Category::isSmall) {
- return;
- }
- if (c == Category::isMedium) {
- free(ml_.data_);
+ if (category() == Category::isSmall) {
return;
}
- RefCounted::decrementRefs(ml_.data_);
+ destroyMediumLarge();
}
// Snatches a previously mallocated string. The parameter "size"
fbstring_detail::assume_unreachable();
}
- const Char * c_str() const {
- auto const c = category();
- if (c == Category::isSmall) {
- FBSTRING_ASSERT(small_[smallSize()] == '\0');
- return small_;
- }
- FBSTRING_ASSERT(c == Category::isMedium || c == Category::isLarge);
- FBSTRING_ASSERT(ml_.data_[ml_.size_] == '\0');
- return ml_.data_;
+ const Char* c_str() const {
+ const Char* ptr = ml_.data_;
+ // With this syntax, GCC and Clang generate a CMOV instead of a branch.
+ ptr = (category() == Category::isSmall) ? small_ : ptr;
+ return ptr;
}
void shrink(const size_t delta) {
}
}
+ FOLLY_MALLOC_NOINLINE
void reserve(size_t minCapacity, bool disableSSO = FBSTRING_DISABLE_SSO) {
switch (category()) {
case Category::isSmall:
}
size_t size() const {
- return category() == Category::isSmall ? smallSize() : ml_.size_;
+ size_t ret = ml_.size_;
+ /* static */ if (kIsLittleEndian) {
+ // We can save a couple instructions, because the category is
+ // small iff the last char, as unsigned, is <= maxSmallSize.
+ typedef typename std::make_unsigned<Char>::type UChar;
+ auto maybeSmallSize = size_t(maxSmallSize) -
+ size_t(static_cast<UChar>(small_[maxSmallSize]));
+ // With this syntax, GCC and Clang generate a CMOV instead of a branch.
+ ret = (static_cast<ssize_t>(maybeSmallSize) >= 0) ? maybeSmallSize : ret;
+ } else {
+ ret = (category() == Category::isSmall) ? smallSize() : ret;
+ }
+ return ret;
}
size_t capacity() const {
// Disabled
fbstring_core & operator=(const fbstring_core & rhs);
- // Equivalent to setSmallSize(0) but a few ns faster in
- // microbenchmarks.
void reset() {
- ml_.capacity_ = kIsLittleEndian
- ? maxSmallSize << (8 * (sizeof(size_t) - sizeof(Char)))
- : maxSmallSize << 2;
- small_[0] = '\0';
- FBSTRING_ASSERT(category() == Category::isSmall && size() == 0);
+ setSmallSize(0);
+ }
+
+ FOLLY_MALLOC_NOINLINE void destroyMediumLarge() noexcept {
+ auto const c = category();
+ FBSTRING_ASSERT(c != Category::isSmall);
+ if (c == Category::isMedium) {
+ free(ml_.data_);
+ } else {
+ RefCounted::decrementRefs(ml_.data_);
+ }
}
struct RefCounted {
static RefCounted * create(const Char * data, size_t * size) {
const size_t effectiveSize = *size;
auto result = create(size);
- fbstring_detail::podCopy(data, data + effectiveSize, result->data_);
+ if (FBSTRING_LIKELY(effectiveSize > 0)) {
+ fbstring_detail::podCopy(data, data + effectiveSize, result->data_);
+ }
return result;
}
}
};
- typedef std::conditional<sizeof(size_t) == 4, uint32_t, uint64_t>::type
- category_type;
+ typedef uint8_t 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,
+ isMedium = kIsLittleEndian ? 0x80 : 0x2,
+ isLarge = kIsLittleEndian ? 0x40 : 0x1,
};
Category category() const {
// works for both big-endian and little-endian
- return static_cast<Category>(ml_.capacity_ & categoryExtractMask);
+ return static_cast<Category>(bytes_[lastChar] & categoryExtractMask);
}
struct MediumLarge {
}
void setCapacity(size_t cap, Category cat) {
- capacity_ = kIsLittleEndian
- ? cap | static_cast<category_type>(cat)
- : (cap << 2) | static_cast<category_type>(cat);
+ capacity_ = kIsLittleEndian
+ ? cap | (static_cast<size_t>(cat) << kCategoryShift)
+ : (cap << 2) | static_cast<size_t>(cat);
}
};
union {
+ uint8_t bytes_[sizeof(MediumLarge)]; // For accessing the last byte.
Char small_[sizeof(MediumLarge) / sizeof(Char)];
MediumLarge ml_;
};
- enum : size_t {
- lastChar = sizeof(MediumLarge) - 1,
- maxSmallSize = lastChar / sizeof(Char),
- maxMediumSize = 254 / sizeof(Char), // coincides with the small
- // bin size in dlmalloc
- categoryExtractMask = kIsLittleEndian
- ? sizeof(size_t) == 4 ? 0xC0000000 : size_t(0xC000000000000000)
- : 0x3,
- capacityExtractMask = kIsLittleEndian
- ? ~categoryExtractMask
- : 0x0 /*unused*/,
- };
+ constexpr static size_t lastChar = sizeof(MediumLarge) - 1;
+ constexpr static size_t maxSmallSize = lastChar / sizeof(Char);
+ constexpr static size_t maxMediumSize = 254 / sizeof(Char);
+ constexpr static uint8_t categoryExtractMask = kIsLittleEndian ? 0xC0 : 0x3;
+ constexpr static size_t kCategoryShift = (sizeof(size_t) - 1) * 8;
+ constexpr static size_t capacityExtractMask = kIsLittleEndian
+ ? ~(size_t(categoryExtractMask) << kCategoryShift)
+ : 0x0 /* unused */;
+
static_assert(!(sizeof(MediumLarge) % sizeof(Char)),
"Corrupt memory layout for fbstring.");
void shrinkMedium(size_t delta);
void shrinkLarge(size_t delta);
+ void unshare(size_t minCapacity = 0);
Char* mutableDataLarge();
};
}
template <class Char>
-inline void fbstring_core<Char>::copyMedium(const fbstring_core& rhs) {
+FOLLY_MALLOC_NOINLINE inline void fbstring_core<Char>::copyMedium(
+ const fbstring_core& rhs) {
// Medium strings are copied eagerly. Don't forget to allocate
// one extra Char for the null terminator.
auto const allocSize = goodMallocSize((1 + rhs.ml_.size_) * sizeof(Char));
}
template <class Char>
-inline void fbstring_core<Char>::copyLarge(const fbstring_core& rhs) {
+FOLLY_MALLOC_NOINLINE inline void fbstring_core<Char>::copyLarge(
+ const fbstring_core& rhs) {
// Large strings are just refcounted
ml_ = rhs.ml_;
RefCounted::incrementRefs(ml_.data_);
}
template <class Char>
-inline void fbstring_core<Char>::initMedium(
+FOLLY_MALLOC_NOINLINE inline void fbstring_core<Char>::initMedium(
const Char* const data, const size_t size) {
// Medium strings are allocated normally. Don't forget to
// allocate one extra Char for the terminating null.
auto const allocSize = goodMallocSize((1 + size) * sizeof(Char));
ml_.data_ = static_cast<Char*>(checkedMalloc(allocSize));
- fbstring_detail::podCopy(data, data + size, ml_.data_);
+ if (FBSTRING_LIKELY(size > 0)) {
+ fbstring_detail::podCopy(data, data + size, ml_.data_);
+ }
ml_.size_ = size;
ml_.setCapacity(allocSize / sizeof(Char) - 1, Category::isMedium);
ml_.data_[size] = '\0';
}
template <class Char>
-inline void fbstring_core<Char>::initLarge(
+FOLLY_MALLOC_NOINLINE inline void fbstring_core<Char>::initLarge(
const Char* const data, const size_t size) {
// Large strings are allocated differently
size_t effectiveCapacity = size;
ml_.data_[size] = '\0';
}
+template <class Char>
+FOLLY_MALLOC_NOINLINE inline void fbstring_core<Char>::unshare(
+ size_t minCapacity) {
+ FBSTRING_ASSERT(category() == Category::isLarge);
+ size_t effectiveCapacity = std::max(minCapacity, ml_.capacity());
+ auto const newRC = RefCounted::create(&effectiveCapacity);
+ // If this fails, someone placed the wrong capacity in an
+ // fbstring.
+ FBSTRING_ASSERT(effectiveCapacity >= ml_.capacity());
+ // Also copies terminator.
+ fbstring_detail::podCopy(ml_.data_, ml_.data_ + ml_.size_ + 1, newRC->data_);
+ RefCounted::decrementRefs(ml_.data_);
+ ml_.data_ = newRC->data_;
+ ml_.setCapacity(effectiveCapacity, Category::isLarge);
+ // size_ remains unchanged.
+}
+
template <class Char>
inline Char* fbstring_core<Char>::mutableDataLarge() {
FBSTRING_ASSERT(category() == Category::isLarge);
- if (RefCounted::refs(ml_.data_) > 1) {
- // Ensure unique.
- size_t effectiveCapacity = ml_.capacity();
- auto const newRC = RefCounted::create(&effectiveCapacity);
- // If this fails, someone placed the wrong capacity in an
- // fbstring.
- FBSTRING_ASSERT(effectiveCapacity >= ml_.capacity());
- // Also copies terminator.
- fbstring_detail::podCopy(
- ml_.data_, ml_.data_ + ml_.size_ + 1, newRC->data_);
- RefCounted::decrementRefs(ml_.data_);
- ml_.data_ = newRC->data_;
+ if (RefCounted::refs(ml_.data_) > 1) { // Ensure unique.
+ unshare();
}
return ml_.data_;
}
template <class Char>
-inline void fbstring_core<Char>::reserveLarge(size_t minCapacity) {
+FOLLY_MALLOC_NOINLINE inline void fbstring_core<Char>::reserveLarge(
+ size_t minCapacity) {
FBSTRING_ASSERT(category() == Category::isLarge);
- // Ensure unique
- if (RefCounted::refs(ml_.data_) > 1) {
+ if (RefCounted::refs(ml_.data_) > 1) { // Ensure unique
// We must make it unique regardless; in-place reallocation is
// useless if the string is shared. In order to not surprise
// people, reserve the new block at current capacity or
// more. That way, a string's capacity never shrinks after a
// call to reserve.
- minCapacity = std::max(minCapacity, ml_.capacity());
- auto const newRC = RefCounted::create(&minCapacity);
- // Also copies terminator.
- fbstring_detail::podCopy(
- ml_.data_, ml_.data_ + ml_.size_ + 1, newRC->data_);
- RefCounted::decrementRefs(ml_.data_);
- ml_.data_ = newRC->data_;
- ml_.setCapacity(minCapacity, Category::isLarge);
- // size remains unchanged
+ unshare(minCapacity);
} else {
// String is not shared, so let's try to realloc (if needed)
if (minCapacity > ml_.capacity()) {
}
template <class Char>
-inline void fbstring_core<Char>::reserveMedium(const size_t minCapacity) {
+FOLLY_MALLOC_NOINLINE inline void fbstring_core<Char>::reserveMedium(
+ const size_t minCapacity) {
FBSTRING_ASSERT(category() == Category::isMedium);
// String is not shared
if (minCapacity <= ml_.capacity()) {
}
template <class Char>
-inline void fbstring_core<Char>::reserveSmall(
+FOLLY_MALLOC_NOINLINE inline void fbstring_core<Char>::reserveSmall(
size_t minCapacity, const bool disableSSO) {
FBSTRING_ASSERT(category() == Category::isSmall);
if (!disableSSO && minCapacity <= maxSmallSize) {
assign(str, pos, n);
}
+ FOLLY_MALLOC_NOINLINE
/* implicit */ basic_fbstring(const value_type* s, const A& /*a*/ = A())
- : store_(s, basic_fbstring::traitsLength(s)) {
- }
+ : store_(s, traitsLength(s)) {}
+ FOLLY_MALLOC_NOINLINE
basic_fbstring(const value_type* s, size_type n, const A& /*a*/ = A())
: store_(s, n) {
}
+ FOLLY_MALLOC_NOINLINE
basic_fbstring(size_type n, value_type c, const A& /*a*/ = A()) {
auto const pData = store_.expandNoinit(n);
fbstring_detail::podFill(pData, pData + n, c);
}
template <class InIt>
- basic_fbstring(
+ FOLLY_MALLOC_NOINLINE basic_fbstring(
InIt begin,
InIt end,
typename std::enable_if<
}
// Specialization for const char*, const char*
+ FOLLY_MALLOC_NOINLINE
basic_fbstring(const value_type* b, const value_type* e, const A& /*a*/ = A())
: store_(b, e - b) {
}
}
// Construction from initialization list
+ FOLLY_MALLOC_NOINLINE
basic_fbstring(std::initializer_list<value_type> il) {
assign(il.begin(), il.end());
}
- ~basic_fbstring() noexcept {
- }
+ ~basic_fbstring() noexcept {}
basic_fbstring& operator=(const basic_fbstring& lhs);
basic_fbstring& append(const value_type* s, size_type n);
basic_fbstring& append(const value_type* s) {
- return append(s, traits_type::length(s));
+ return append(s, traitsLength(s));
}
basic_fbstring& append(size_type n, value_type c);
basic_fbstring& assign(const value_type* s, const size_type n);
basic_fbstring& assign(const value_type* s) {
- return assign(s, traits_type::length(s));
+ return assign(s, traitsLength(s));
}
basic_fbstring& assign(std::initializer_list<value_type> il) {
}
basic_fbstring& insert(size_type pos, const value_type* s) {
- return insert(pos, s, traits_type::length(s));
+ return insert(pos, s, traitsLength(s));
}
basic_fbstring& insert(size_type pos, size_type n, value_type c) {
// Replaces at most n1 chars of *this, starting with pos, with chars from s
basic_fbstring& replace(size_type pos, size_type n1, const value_type* s) {
- return replace(pos, n1, s, traits_type::length(s));
+ return replace(pos, n1, s, traitsLength(s));
}
// Replaces at most n1 chars of *this, starting with pos, with n2
}
basic_fbstring& replace(iterator i1, iterator i2, const value_type* s) {
- return replace(i1, i2, s, traits_type::length(s));
+ return replace(i1, i2, s, traitsLength(s));
}
private:
const;
size_type find(const value_type* s, size_type pos = 0) const {
- return find(s, pos, traits_type::length(s));
+ return find(s, pos, traitsLength(s));
}
size_type find (value_type c, size_type pos = 0) const {
size_type rfind(const value_type* s, size_type pos, size_type n) const;
size_type rfind(const value_type* s, size_type pos = npos) const {
- return rfind(s, pos, traits_type::length(s));
+ return rfind(s, pos, traitsLength(s));
}
size_type rfind(value_type c, size_type pos = npos) const {
const;
size_type find_first_of(const value_type* s, size_type pos = 0) const {
- return find_first_of(s, pos, traits_type::length(s));
+ return find_first_of(s, pos, traitsLength(s));
}
size_type find_first_of(value_type c, size_type pos = 0) const {
size_type find_last_of (const value_type* s,
size_type pos = npos) const {
- return find_last_of(s, pos, traits_type::length(s));
+ return find_last_of(s, pos, traitsLength(s));
}
size_type find_last_of (value_type c, size_type pos = npos) const {
size_type find_first_not_of(const value_type* s,
size_type pos = 0) const {
- return find_first_not_of(s, pos, traits_type::length(s));
+ return find_first_not_of(s, pos, traitsLength(s));
}
size_type find_first_not_of(value_type c, size_type pos = 0) const {
size_type find_last_not_of(const value_type* s,
size_type pos = npos) const {
- return find_last_not_of(s, pos, traits_type::length(s));
+ return find_last_not_of(s, pos, traitsLength(s));
}
size_type find_last_not_of (value_type c, size_type pos = npos) const {
int compare(size_type pos1, size_type n1,
const value_type* s) const {
- return compare(pos1, n1, s, traits_type::length(s));
+ return compare(pos1, n1, s, traitsLength(s));
}
int compare(size_type pos1, size_type n1,
// Code from Jean-Francois Bastien (03/26/2007)
int compare(const value_type* s) const {
- // Could forward to compare(0, size(), s, traits_type::length(s))
+ // Could forward to compare(0, size(), s, traitsLength(s))
// but that does two extra checks
- const size_type n1(size()), n2(traits_type::length(s));
+ const size_type n1(size()), n2(traitsLength(s));
const int r = traits_type::compare(data(), s, std::min(n1, n2));
return r != 0 ? r : n1 > n2 ? 1 : n1 < n2 ? -1 : 0;
}
};
template <typename E, class T, class A, class S>
-inline typename basic_fbstring<E, T, A, S>::size_type
+FOLLY_MALLOC_NOINLINE inline typename basic_fbstring<E, T, A, S>::size_type
basic_fbstring<E, T, A, S>::traitsLength(const value_type* s) {
return s ? traits_type::length(s)
: (std::__throw_logic_error(
}
template <typename E, class T, class A, class S>
-inline basic_fbstring<E, T, A, S>& basic_fbstring<E, T, A, S>::append(
- const value_type* s, size_type n) {
+FOLLY_MALLOC_NOINLINE inline basic_fbstring<E, T, A, S>&
+basic_fbstring<E, T, A, S>::append(const value_type* s, size_type n) {
Invariant checker(*this);
if (FBSTRING_UNLIKELY(!n)) {
}
template <typename E, class T, class A, class S>
-inline basic_fbstring<E, T, A, S>& basic_fbstring<E, T, A, S>::assign(
- const value_type* s, const size_type n) {
+FOLLY_MALLOC_NOINLINE inline basic_fbstring<E, T, A, S>&
+basic_fbstring<E, T, A, S>::assign(const value_type* s, const size_type n) {
Invariant checker(*this);
- // s can alias this, we need to use podMove.
if (n == 0) {
resize(0);
} else if (size() >= n) {