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silo_small_vector.h
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silo_small_vector.h
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#ifndef _SILO_SMALL_VECTOR_H_
#define _SILO_SMALL_VECTOR_H_
#include <algorithm>
#include <vector>
#include <type_traits>
#include "macros.h"
#include "masstree/compiler.hh"
/**
* References are not guaranteed to be stable across mutation
*
* XXX(stephentu): allow custom allocator
*/
template <typename T, size_t SmallSize = SMALL_SIZE_VEC>
class silo_small_vector {
typedef std::vector<T> large_vector_type;
static const bool is_trivially_destructible =
mass::is_trivially_destructible<T>::value;
// std::is_trivially_copyable not supported in g++-4.7
static const bool is_trivially_copyable = std::is_scalar<T>::value;
public:
typedef T value_type;
typedef T & reference;
typedef const T & const_reference;
typedef size_t size_type;
silo_small_vector() : n(0), large_elems(0) {}
~silo_small_vector()
{
clearDestructive();
}
silo_small_vector(const silo_small_vector &that)
: n(0), large_elems(0)
{
assignFrom(that);
}
// not efficient, don't use in performance critical parts
silo_small_vector(std::initializer_list<T> l)
: n(0), large_elems(nullptr)
{
if (l.size() > SmallSize) {
large_elems = new large_vector_type(l);
} else {
for (auto &p : l)
push_back(p);
}
}
silo_small_vector &
operator=(const silo_small_vector &that)
{
assignFrom(that);
return *this;
}
inline size_t
size() const
{
if (unlikely(large_elems))
return large_elems->size();
return n;
}
inline bool
empty() const
{
return size() == 0;
}
inline reference
front()
{
if (unlikely(large_elems))
return large_elems->front();
INVARIANT(n > 0);
INVARIANT(n <= SmallSize);
return *ptr();
}
inline const_reference
front() const
{
return const_cast<silo_small_vector *>(this)->front();
}
inline reference
back()
{
if (unlikely(large_elems))
return large_elems->back();
INVARIANT(n > 0);
INVARIANT(n <= SmallSize);
return ptr()[n - 1];
}
inline const_reference
back() const
{
return const_cast<silo_small_vector *>(this)->back();
}
inline void
pop_back()
{
if (unlikely(large_elems)) {
large_elems->pop_back();
return;
}
INVARIANT(n > 0);
if (!is_trivially_destructible)
ptr()[n - 1].~T();
n--;
}
inline void
push_back(const T &obj)
{
emplace_back(obj);
}
inline void
push_back(T &&obj)
{
emplace_back(std::move(obj));
}
// C++11 goodness- a strange syntax this is
template <class... Args>
inline void
emplace_back(Args &&... args)
{
if (unlikely(large_elems)) {
INVARIANT(!n);
large_elems->emplace_back(std::forward<Args>(args)...);
return;
}
if (unlikely(n == SmallSize)) {
large_elems = new large_vector_type(ptr(), ptr() + n);
large_elems->emplace_back(std::forward<Args>(args)...);
n = 0;
return;
}
INVARIANT(n < SmallSize);
new (&(ptr()[n++])) T(std::forward<Args>(args)...);
}
inline reference
operator[](int i)
{
if (unlikely(large_elems))
return large_elems->operator[](i);
return ptr()[i];
}
inline const_reference
operator[](int i) const
{
return const_cast<silo_small_vector *>(this)->operator[](i);
}
void
clear()
{
if (unlikely(large_elems)) {
INVARIANT(!n);
large_elems->clear();
return;
}
if (!is_trivially_destructible)
for (size_t i = 0; i < n; i++)
ptr()[i].~T();
n = 0;
}
inline void
reserve(size_t n)
{
if (unlikely(large_elems))
large_elems->reserve(n);
}
// non-standard API
inline bool is_small_type() const { return !large_elems; }
template <typename Compare = std::less<T>>
inline void
sort(Compare c = Compare())
{
if (unlikely(large_elems))
std::sort(large_elems->begin(), large_elems->end(), c);
else
std::sort(small_begin(), small_end(), c);
}
private:
void
clearDestructive()
{
if (unlikely(large_elems)) {
INVARIANT(!n);
delete large_elems;
large_elems = NULL;
return;
}
if (!is_trivially_destructible)
for (size_t i = 0; i < n; i++)
ptr()[i].~T();
n = 0;
}
template <typename ObjType>
class small_iterator_ : public std::iterator<std::bidirectional_iterator_tag, ObjType> {
friend class silo_small_vector;
public:
inline small_iterator_() : p(0) {}
template <typename O>
inline small_iterator_(const small_iterator_<O> &other)
: p(other.p)
{}
inline ObjType &
operator*() const
{
return *p;
}
inline ObjType *
operator->() const
{
return p;
}
inline bool
operator==(const small_iterator_ &o) const
{
return p == o.p;
}
inline bool
operator!=(const small_iterator_ &o) const
{
return !operator==(o);
}
inline bool
operator<(const small_iterator_ &o) const
{
return p < o.p;
}
inline bool
operator>=(const small_iterator_ &o) const
{
return !operator<(o);
}
inline bool
operator>(const small_iterator_ &o) const
{
return p > o.p;
}
inline bool
operator<=(const small_iterator_ &o) const
{
return !operator>(o);
}
inline small_iterator_ &
operator+=(int n)
{
p += n;
return *this;
}
inline small_iterator_ &
operator-=(int n)
{
p -= n;
return *this;
}
inline small_iterator_
operator+(int n) const
{
small_iterator_ cpy = *this;
return cpy += n;
}
inline small_iterator_
operator-(int n) const
{
small_iterator_ cpy = *this;
return cpy -= n;
}
inline intptr_t
operator-(const small_iterator_ &o) const
{
return p - o.p;
}
inline small_iterator_ &
operator++()
{
++p;
return *this;
}
inline small_iterator_
operator++(int)
{
small_iterator_ cur = *this;
++(*this);
return cur;
}
inline small_iterator_ &
operator--()
{
--p;
return *this;
}
inline small_iterator_
operator--(int)
{
small_iterator_ cur = *this;
--(*this);
return cur;
}
protected:
inline small_iterator_(ObjType *p) : p(p) {}
private:
ObjType *p;
};
template <typename ObjType, typename SmallTypeIter, typename LargeTypeIter>
class iterator_ : public std::iterator<std::bidirectional_iterator_tag, ObjType> {
friend class silo_small_vector;
public:
inline iterator_() : large(false) {}
template <typename O, typename S, typename L>
inline iterator_(const iterator_<O, S, L> &other)
: large(other.large),
small_it(other.small_it),
large_it(other.large_it)
{}
inline ObjType &
operator*() const
{
if (unlikely(large))
return *large_it;
return *small_it;
}
inline ObjType *
operator->() const
{
if (unlikely(large))
return &(*large_it);
return &(*small_it);
}
inline bool
operator==(const iterator_ &o) const
{
if (unlikely(large))
return large_it == o.large_it;
return small_it == o.small_it;
}
inline bool
operator!=(const iterator_ &o) const
{
return !operator==(o);
}
inline bool
operator<(const iterator_ &o) const
{
if (unlikely(large))
return large_it < o.large_it;
return small_it < o.small_it;
}
inline bool
operator>=(const iterator_ &o) const
{
return !operator<(o);
}
inline bool
operator>(const iterator_ &o) const
{
if (unlikely(large))
return large_it > o.large_it;
return small_it > o.small_it;
}
inline bool
operator<=(const iterator_ &o) const
{
return !operator>(o);
}
inline iterator_ &
operator+=(int n)
{
if (unlikely(large))
large_it += n;
else
small_it += n;
return *this;
}
inline iterator_ &
operator-=(int n)
{
if (unlikely(large))
large_it -= n;
else
small_it -= n;
return *this;
}
inline iterator_
operator+(int n) const
{
iterator_ cpy = *this;
return cpy += n;
}
inline iterator_
operator-(int n) const
{
iterator_ cpy = *this;
return cpy -= n;
}
inline intptr_t
operator-(const iterator_ &o) const
{
if (unlikely(large))
return large_it - o.large_it;
else
return small_it - o.small_it;
}
inline iterator_ &
operator++()
{
if (unlikely(large))
++large_it;
else
++small_it;
return *this;
}
inline iterator_
operator++(int)
{
iterator_ cur = *this;
++(*this);
return cur;
}
inline iterator_ &
operator--()
{
if (unlikely(large))
--large_it;
else
--small_it;
return *this;
}
inline iterator_
operator--(int)
{
iterator_ cur = *this;
--(*this);
return cur;
}
protected:
iterator_(SmallTypeIter small_it)
: large(false), small_it(small_it), large_it() {}
iterator_(LargeTypeIter large_it)
: large(true), small_it(), large_it(large_it) {}
private:
bool large;
SmallTypeIter small_it;
LargeTypeIter large_it;
};
typedef small_iterator_<T> small_iterator;
typedef small_iterator_<const T> const_small_iterator;
typedef typename large_vector_type::iterator large_iterator;
typedef typename large_vector_type::const_iterator const_large_iterator;
inline small_iterator
small_begin()
{
INVARIANT(!large_elems);
return small_iterator(ptr());
}
inline const_small_iterator
small_begin() const
{
INVARIANT(!large_elems);
return const_small_iterator(ptr());
}
inline small_iterator
small_end()
{
INVARIANT(!large_elems);
return small_iterator(ptr() + n);
}
inline const_small_iterator
small_end() const
{
INVARIANT(!large_elems);
return const_small_iterator(ptr() + n);
}
public:
typedef iterator_<T, small_iterator, large_iterator> iterator;
typedef iterator_<const T, const_small_iterator, const_large_iterator> const_iterator;
typedef std::reverse_iterator<iterator> reverse_iterator;
typedef std::reverse_iterator<const_iterator> const_reverse_iterator;
inline iterator
begin()
{
if (unlikely(large_elems))
return iterator(large_elems->begin());
return iterator(small_begin());
}
inline const_iterator
begin() const
{
if (unlikely(large_elems))
return const_iterator(large_elems->begin());
return const_iterator(small_begin());
}
inline iterator
end()
{
if (unlikely(large_elems))
return iterator(large_elems->end());
return iterator(small_end());
}
inline const_iterator
end() const
{
if (unlikely(large_elems))
return const_iterator(large_elems->end());
return const_iterator(small_end());
}
inline reverse_iterator
rbegin()
{
return reverse_iterator(end());
}
inline const_reverse_iterator
rbegin() const
{
return const_reverse_iterator(end());
}
inline reverse_iterator
rend()
{
return reverse_iterator(begin());
}
inline const_reverse_iterator
rend() const
{
return const_reverse_iterator(begin());
}
private:
void
assignFrom(const silo_small_vector &that)
{
if (unlikely(this == &that))
return;
clearDestructive();
if (unlikely(that.large_elems)) {
large_elems = new large_vector_type(*that.large_elems);
} else {
INVARIANT(that.n <= SmallSize);
if (is_trivially_copyable) {
NDB_MEMCPY(ptr(), that.ptr(), that.n * sizeof(T));
} else {
for (size_t i = 0; i < that.n; i++)
new (&(ptr()[i])) T(that.ptr()[i]);
}
n = that.n;
}
}
inline ALWAYS_INLINE T *
ptr()
{
return reinterpret_cast<T *>(&small_elems_buf[0]);
}
inline ALWAYS_INLINE const T *
ptr() const
{
return reinterpret_cast<const T *>(&small_elems_buf[0]);
}
size_t n;
char small_elems_buf[sizeof(T) * SmallSize];
large_vector_type *large_elems;
};
#endif /* _SILO_SMALL_VECTOR_H_ */