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glm/test/external/boost/wave/util/flex_string.hpp

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/*=============================================================================
Boost.Wave: A Standard compliant C++ preprocessor library
http://www.boost.org/
Copyright (c) 2001 by Andrei Alexandrescu. Distributed under the Boost
Software License, Version 1.0. (See accompanying file
LICENSE_1_0.txt or copy at http://www.boost.org/LICENSE_1_0.txt)
=============================================================================*/
// This code is taken from:
// Andrei Alexandrescu, Generic<Programming>: A Policy-Based basic_string
// Implementation. http://www.cuj.com/documents/s=7994/cujcexp1906alexandr/
//
// #HK030306:
// - Moved into the namespace boost::wave::util
// - Added a bunch of missing typename(s)
// - Integrated with boost config
// - Added a missing header include
// - Added special constructors and operator= to allow CowString to be
// a real COW-string (removed unnecessary data copying)
// - Fixed a string terminating bug in append
//
// #HK040109:
// - Incorporated the changes from Andrei's latest version of this class
//
// #HK070307:
// - Once again incorporated the changes from Andrei's latest version of
// this class
//
// #HK090523:
// - Incorporated the changes from latest version of flex_string as
// maintained in Loki
#ifndef FLEX_STRING_INC_
#define FLEX_STRING_INC_
/*
////////////////////////////////////////////////////////////////////////////////
template <typename E, class A = @>
class StoragePolicy
{
typedef E value_type;
typedef @ iterator;
typedef @ const_iterator;
typedef A allocator_type;
typedef @ size_type;
StoragePolicy(const StoragePolicy& s);
StoragePolicy(const A&);
StoragePolicy(const E* s, size_type len, const A&);
StoragePolicy(size_type len, E c, const A&);
~StoragePolicy();
iterator begin();
const_iterator begin() const;
iterator end();
const_iterator end() const;
size_type size() const;
size_type max_size() const;
size_type capacity() const;
void reserve(size_type res_arg);
void append(const E* s, size_type sz);
template <class InputIterator>
void append(InputIterator b, InputIterator e);
void resize(size_type newSize, E fill);
void swap(StoragePolicy& rhs);
const E* c_str() const;
const E* data() const;
A get_allocator() const;
};
////////////////////////////////////////////////////////////////////////////////
*/
#include <boost/config.hpp>
#include <boost/assert.hpp>
#include <boost/throw_exception.hpp>
#include <boost/iterator/reverse_iterator.hpp>
#include <boost/wave/wave_config.hpp>
#if BOOST_WAVE_SERIALIZATION != 0
#include <boost/serialization/serialization.hpp>
#include <boost/serialization/split_free.hpp>
#include <boost/serialization/collections_save_imp.hpp>
#include <boost/serialization/collections_load_imp.hpp>
#define BOOST_WAVE_FLEX_STRING_SERIALIZATION_HACK 1
#endif
#include <memory>
#include <new>
#include <string>
#include <vector>
#include <algorithm>
#include <functional>
#include <limits>
#include <stdexcept>
#include <ios>
#include <cstddef>
#include <cstring>
#include <cstdlib>
// this must occur after all of the includes and before any code appears
#ifdef BOOST_HAS_ABI_HEADERS
#include BOOST_ABI_PREFIX
#endif
///////////////////////////////////////////////////////////////////////////////
namespace boost {
namespace wave {
namespace util {
namespace flex_string_details
{
template <class InIt, class OutIt>
OutIt copy_n(InIt b,
typename std::iterator_traits<InIt>::difference_type n, OutIt d)
{
for (/**/; n != 0; --n, ++b, ++d)
{
*d = *b;
}
return d;
}
template <class Pod, class T>
inline void pod_fill(Pod* b, Pod* e, T c)
{
switch ((e - b) & 7)
{
case 0:
while (b != e)
{
*b = c; ++b;
case 7: *b = c; ++b;
case 6: *b = c; ++b;
case 5: *b = c; ++b;
case 4: *b = c; ++b;
case 3: *b = c; ++b;
case 2: *b = c; ++b;
case 1: *b = c; ++b;
}
}
}
template <class Pod>
inline void pod_move(const Pod* b, const Pod* e, Pod* d)
{
using namespace std;
memmove(d, b, (e - b) * sizeof(*b));
}
template <class Pod>
inline Pod* pod_copy(const Pod* b, const Pod* e, Pod* d)
{
const std::size_t s = e - b;
using namespace std;
memcpy(d, b, s * sizeof(*b));
return d + s;
}
template <typename T> struct get_unsigned
{
typedef T result;
};
template <> struct get_unsigned<char>
{
typedef unsigned char result;
};
template <> struct get_unsigned<signed char>
{
typedef unsigned char result;
};
template <> struct get_unsigned<short int>
{
typedef unsigned short int result;
};
template <> struct get_unsigned<int>
{
typedef unsigned int result;
};
template <> struct get_unsigned<long int>
{
typedef unsigned long int result;
};
enum Shallow {};
}
template <class T> class mallocator
{
public:
typedef T value_type;
typedef value_type* pointer;
typedef const value_type* const_pointer;
typedef value_type& reference;
typedef const value_type& const_reference;
typedef std::size_t size_type;
//typedef unsigned int size_type;
//typedef std::ptrdiff_t difference_type;
typedef int difference_type;
template <class U>
struct rebind { typedef mallocator<U> other; };
mallocator() {}
mallocator(const mallocator&) {}
//template <class U>
//mallocator(const mallocator<U>&) {}
~mallocator() {}
pointer address(reference x) const { return &x; }
const_pointer address(const_reference x) const
{
return x;
}
pointer allocate(size_type n, const_pointer = 0)
{
using namespace std;
void* p = malloc(n * sizeof(T));
if (!p) boost::throw_exception(std::bad_alloc());
return static_cast<pointer>(p);
}
void deallocate(pointer p, size_type)
{
using namespace std;
free(p);
}
size_type max_size() const
{
return static_cast<size_type>(-1) / sizeof(T);
}
void construct(pointer p, const value_type& x)
{
new(p) value_type(x);
}
void destroy(pointer p)
{
p->~value_type();
}
private:
void operator=(const mallocator&);
};
template<> class mallocator<void>
{
typedef void value_type;
typedef void* pointer;
typedef const void* const_pointer;
template <class U>
struct rebind { typedef mallocator<U> other; };
};
template <class T>
inline bool operator==(const mallocator<T>&,
const mallocator<T>&) {
return true;
}
template <class T>
inline bool operator!=(const mallocator<T>&,
const mallocator<T>&) {
return false;
}
template <class Allocator>
typename Allocator::pointer Reallocate(
Allocator& alloc,
typename Allocator::pointer p,
typename Allocator::size_type oldObjCount,
typename Allocator::size_type newObjCount,
void*)
{
// @@@ not implemented
return NULL;
}
template <class Allocator>
typename Allocator::pointer Reallocate(
Allocator& alloc,
typename Allocator::pointer p,
typename Allocator::size_type oldObjCount,
typename Allocator::size_type newObjCount,
mallocator<void>*)
{
// @@@ not implemented
return NULL;
}
////////////////////////////////////////////////////////////////////////////////
// class template SimpleStringStorage
// Allocates memory with malloc
////////////////////////////////////////////////////////////////////////////////
template <typename E, class A = std::allocator<E> >
class SimpleStringStorage
{
// The "public" below exists because MSVC can't do template typedefs
public:
struct Data
{
Data() : pEnd_(buffer_), pEndOfMem_(buffer_) { buffer_[0] = E(0); }
E* pEnd_;
E* pEndOfMem_;
E buffer_[1];
};
static const Data emptyString_;
typedef typename A::size_type size_type;
private:
Data* pData_;
void Init(size_type size, size_type capacity)
{
BOOST_ASSERT(size <= capacity);
if (capacity == 0)
{
pData_ = const_cast<Data*>(&emptyString_);
}
else
{
// 11-17-2000: comment added:
// No need to allocate (capacity + 1) to
// accommodate the terminating 0, because Data already
// has one one character in there
pData_ = static_cast<Data*>(
malloc(sizeof(Data) + capacity * sizeof(E)));
if (!pData_) boost::throw_exception(std::bad_alloc());
pData_->pEnd_ = pData_->buffer_ + size;
pData_->pEndOfMem_ = pData_->buffer_ + capacity;
}
}
private:
// Warning - this doesn't initialize pData_. Used in reserve()
SimpleStringStorage()
{ }
public:
typedef E value_type;
typedef E* iterator;
typedef const E* const_iterator;
typedef A allocator_type;
SimpleStringStorage(const SimpleStringStorage& rhs)
{
const size_type sz = rhs.size();
Init(sz, sz);
if (sz) flex_string_details::pod_copy(rhs.begin(), rhs.end(), begin());
}
SimpleStringStorage(const SimpleStringStorage& s,
flex_string_details::Shallow)
: pData_(s.pData_)
{
}
SimpleStringStorage(const A&)
{ pData_ = const_cast<Data*>(&emptyString_); }
SimpleStringStorage(const E* s, size_type len, const A&)
{
Init(len, len);
flex_string_details::pod_copy(s, s + len, begin());
}
SimpleStringStorage(size_type len, E c, const A&)
{
Init(len, len);
flex_string_details::pod_fill(begin(), end(), c);
}
SimpleStringStorage& operator=(const SimpleStringStorage& rhs)
{
const size_type sz = rhs.size();
reserve(sz);
flex_string_details::pod_copy(&*rhs.begin(), &*rhs.end(), begin());
pData_->pEnd_ = &*begin() + sz;
return *this;
}
~SimpleStringStorage()
{
BOOST_ASSERT(begin() <= end());
if (pData_ != &emptyString_) free(pData_);
}
iterator begin()
{ return pData_->buffer_; }
const_iterator begin() const
{ return pData_->buffer_; }
iterator end()
{ return pData_->pEnd_; }
const_iterator end() const
{ return pData_->pEnd_; }
size_type size() const
{ return pData_->pEnd_ - pData_->buffer_; }
size_type max_size() const
{ return std::size_t(-1) / sizeof(E) - sizeof(Data) - 1; }
size_type capacity() const
{ return pData_->pEndOfMem_ - pData_->buffer_; }
void reserve(size_type res_arg)
{
if (res_arg <= capacity())
{
// @@@ insert shrinkage here if you wish
return;
}
if (pData_ == &emptyString_)
{
Init(0, res_arg);
}
else
{
const size_type sz = size();
void* p = realloc(pData_,
sizeof(Data) + res_arg * sizeof(E));
if (!p) boost::throw_exception(std::bad_alloc());
if (p != pData_)
{
pData_ = static_cast<Data*>(p);
pData_->pEnd_ = pData_->buffer_ + sz;
}
pData_->pEndOfMem_ = pData_->buffer_ + res_arg;
}
}
void append(const E* s, size_type sz)
{
const size_type neededCapacity = size() + sz;
if (capacity() < neededCapacity)
{
const iterator b = begin();
static std::less_equal<const E*> le;
if (le(b, s) && le(s, end()))
{
// aliased
const size_type offset = s - b;
reserve(neededCapacity);
s = begin() + offset;
}
else
{
reserve(neededCapacity);
}
}
flex_string_details::pod_copy(s, s + sz, end());
pData_->pEnd_ += sz;
}
template <class InputIterator>
void append(InputIterator b, InputIterator e)
{
// @@@ todo: optimize this depending on iterator type
for (; b != e; ++b)
{
*this += *b;
}
}
void resize(size_type newSize, E fill)
{
const int delta = int(newSize - size());
if (delta == 0) return;
if (delta > 0)
{
if (newSize > capacity())
{
reserve(newSize);
}
E* e = &*end();
flex_string_details::pod_fill(e, e + delta, fill);
}
pData_->pEnd_ = pData_->buffer_ + newSize;
}
void swap(SimpleStringStorage& rhs)
{
std::swap(pData_, rhs.pData_);
}
const E* c_str() const
{
if (pData_ != &emptyString_) *pData_->pEnd_ = E();
return pData_->buffer_;
}
const E* data() const
{ return pData_->buffer_; }
A get_allocator() const
{ return A(); }
};
template <typename E, class A>
const typename SimpleStringStorage<E, A>::Data
SimpleStringStorage<E, A>::emptyString_ =
typename SimpleStringStorage<E, A>::Data();
////////////////////////////////////////////////////////////////////////////////
// class template AllocatorStringStorage
// Allocates with your allocator
// Takes advantage of the Empty Base Optimization if available
////////////////////////////////////////////////////////////////////////////////
template <typename E, class A = std::allocator<E> >
class AllocatorStringStorage : public A
{
typedef typename A::size_type size_type;
typedef typename SimpleStringStorage<E, A>::Data Data;
void* Alloc(size_type sz, const void* p = 0)
{
return A::allocate(1 + (sz - 1) / sizeof(E),
static_cast<const char*>(p));
}
void* Realloc(void* p, size_type oldSz, size_type newSz)
{
void* r = Alloc(newSz);
flex_string_details::pod_copy(p, p + Min(oldSz, newSz), r);
Free(p, oldSz);
return r;
}
void Free(void* p, size_type sz)
{
A::deallocate(static_cast<E*>(p), sz);
}
Data* pData_;
void Init(size_type size, size_type cap)
{
BOOST_ASSERT(size <= cap);
if (cap == 0)
{
pData_ = const_cast<Data*>(
&SimpleStringStorage<E, A>::emptyString_);
}
else
{
pData_ = static_cast<Data*>(Alloc(
cap * sizeof(E) + sizeof(Data)));
pData_->pEnd_ = pData_->buffer_ + size;
pData_->pEndOfMem_ = pData_->buffer_ + cap;
}
}
public:
typedef E value_type;
typedef E* iterator;
typedef const E* const_iterator;
typedef A allocator_type;
AllocatorStringStorage()
: A(), pData_(0)
{
}
AllocatorStringStorage(const AllocatorStringStorage& rhs)
: A(rhs.get_allocator())
{
const size_type sz = rhs.size();
Init(sz, sz);
if (sz) flex_string_details::pod_copy(rhs.begin(), rhs.end(), begin());
}
AllocatorStringStorage(const AllocatorStringStorage& s,
flex_string_details::Shallow)
: A(s.get_allocator())
{
pData_ = s.pData_;
}
AllocatorStringStorage(const A& a) : A(a)
{
pData_ = const_cast<Data*>(
&SimpleStringStorage<E, A>::emptyString_);
}
AllocatorStringStorage(const E* s, size_type len, const A& a)
: A(a)
{
Init(len, len);
flex_string_details::pod_copy(s, s + len, begin());
}
AllocatorStringStorage(size_type len, E c, const A& a)
: A(a)
{
Init(len, len);
flex_string_details::pod_fill(&*begin(), &*end(), c);
}
AllocatorStringStorage& operator=(const AllocatorStringStorage& rhs)
{
const size_type sz = rhs.size();
reserve(sz);
flex_string_details::pod_copy(&*rhs.begin(), &*rhs.end(), begin());
pData_->pEnd_ = &*begin() + rhs.size();
return *this;
}
~AllocatorStringStorage()
{
if (capacity())
{
Free(pData_,
sizeof(Data) + capacity() * sizeof(E));
}
}
iterator begin()
{ return pData_->buffer_; }
const_iterator begin() const
{ return pData_->buffer_; }
iterator end()
{ return pData_->pEnd_; }
const_iterator end() const
{ return pData_->pEnd_; }
size_type size() const
{ return size_type(end() - begin()); }
size_type max_size() const
{ return A::max_size(); }
size_type capacity() const
{ return size_type(pData_->pEndOfMem_ - pData_->buffer_); }
void resize(size_type n, E c)
{
reserve(n);
iterator newEnd = begin() + n;
iterator oldEnd = end();
if (newEnd > oldEnd)
{
// Copy the characters
flex_string_details::pod_fill(oldEnd, newEnd, c);
}
if (capacity()) pData_->pEnd_ = newEnd;
}
void reserve(size_type res_arg)
{
if (res_arg <= capacity())
{
// @@@ shrink to fit here
return;
}
A& myAlloc = *this;
AllocatorStringStorage newStr(myAlloc);
newStr.Init(size(), res_arg);
flex_string_details::pod_copy(begin(), end(), newStr.begin());
swap(newStr);
}
template <class ForwardIterator>
void append(ForwardIterator b, ForwardIterator e)
{
const size_type
sz = std::distance(b, e),
neededCapacity = size() + sz;
if (capacity() < neededCapacity)
{
// typedef std::less_equal<const E*> le_type;
// BOOST_ASSERT(!(le_type()(begin(), &*b) && le_type()(&*b, end())));
reserve(neededCapacity);
}
std::copy(b, e, end());
pData_->pEnd_ += sz;
}
void swap(AllocatorStringStorage& rhs)
{
// @@@ The following line is commented due to a bug in MSVC
//std::swap(lhsAlloc, rhsAlloc);
std::swap(pData_, rhs.pData_);
}
const E* c_str() const
{
if (pData_ != &SimpleStringStorage<E, A>::emptyString_)
{
*pData_->pEnd_ = E();
}
return &*begin();
}
const E* data() const
{ return &*begin(); }
A get_allocator() const
{ return *this; }
};
////////////////////////////////////////////////////////////////////////////////
// class template VectorStringStorage
// Uses std::vector
// Takes advantage of the Empty Base Optimization if available
////////////////////////////////////////////////////////////////////////////////
template <typename E, class A = std::allocator<E> >
class VectorStringStorage : protected std::vector<E, A>
{
typedef std::vector<E, A> base;
public: // protected:
typedef E value_type;
typedef typename base::iterator iterator;
typedef typename base::const_iterator const_iterator;
typedef A allocator_type;
typedef typename A::size_type size_type;
VectorStringStorage(const VectorStringStorage& s) : base(s)
{ }
VectorStringStorage(const A& a) : base(1, E(), a)
{ }
VectorStringStorage(const E* s, size_type len, const A& a)
: base(a)
{
base::reserve(len + 1);
base::insert(base::end(), s, s + len);
// Terminating zero
base::insert(base::end(), E());
}
VectorStringStorage(size_type len, E c, const A& a)
: base(len + 1, c, a)
{
// Terminating zero
base::back() = E();
}
VectorStringStorage& operator=(const VectorStringStorage& rhs)
{
base& v = *this;
v = rhs;
return *this;
}
iterator begin()
{ return base::begin(); }
const_iterator begin() const
{ return base::begin(); }
iterator end()
{ return base::end() - 1; }
const_iterator end() const
{ return base::end() - 1; }
size_type size() const
{ return base::size() - 1; }
size_type max_size() const
{ return base::max_size() - 1; }
size_type capacity() const
{ return base::capacity() - 1; }
void reserve(size_type res_arg)
{
BOOST_ASSERT(res_arg < max_size());
base::reserve(res_arg + 1);
}
void append(const E* s, size_type sz)
{
// Check for aliasing because std::vector doesn't do it.
static std::less_equal<const E*> le;
if (!base::empty())
{
const E* start = &base::front();
if (le(start, s) && le(s, start + size()))
{
// aliased
const size_type offset = s - start;
reserve(size() + sz);
s = &base::front() + offset;
}
}
base::insert(end(), s, s + sz);
}
template <class InputIterator>
void append(InputIterator b, InputIterator e)
{
base::insert(end(), b, e);
}
void resize(size_type n, E c)
{
base::reserve(n + 1);
base::back() = c;
base::resize(n + 1, c);
base::back() = E();
}
void swap(VectorStringStorage& rhs)
{ base::swap(rhs); }
const E* c_str() const
{ return &*begin(); }
const E* data() const
{ return &*begin(); }
A get_allocator() const
{ return base::get_allocator(); }
};
////////////////////////////////////////////////////////////////////////////////
// class template SmallStringOpt
// Builds the small string optimization over any other storage
////////////////////////////////////////////////////////////////////////////////
template <class Storage, unsigned int threshold,
typename Align = typename Storage::value_type*>
class SmallStringOpt
{
public:
typedef typename Storage::value_type value_type;
typedef value_type* iterator;
typedef const value_type* const_iterator;
typedef typename Storage::allocator_type allocator_type;
typedef typename allocator_type::size_type size_type;
private:
enum { temp1 = threshold * sizeof(value_type) > sizeof(Storage)
? threshold * sizeof(value_type)
: sizeof(Storage) };
enum { temp2 = temp1 > sizeof(Align) ? temp1 : sizeof(Align) };
public:
enum { maxSmallString =
(temp2 + sizeof(value_type) - 1) / sizeof(value_type) };
private:
enum { magic = maxSmallString + 1 };
union
{
mutable value_type buf_[maxSmallString + 1];
Align align_;
};
Storage& GetStorage()
{
BOOST_ASSERT(buf_[maxSmallString] == magic);
Storage* p = reinterpret_cast<Storage*>(&buf_[0]);
return *p;
}
const Storage& GetStorage() const
{
BOOST_ASSERT(buf_[maxSmallString] == magic);
const Storage *p = reinterpret_cast<const Storage*>(&buf_[0]);
return *p;
}
bool Small() const
{
return buf_[maxSmallString] != magic;
}
public:
SmallStringOpt(const SmallStringOpt& s)
{
if (s.Small())
{
flex_string_details::pod_copy(
s.buf_,
s.buf_ + s.size(),
buf_);
}
else
{
new(buf_) Storage(s.GetStorage());
}
buf_[maxSmallString] = s.buf_[maxSmallString];
}
SmallStringOpt(const allocator_type&)
{
buf_[maxSmallString] = maxSmallString;
}
SmallStringOpt(const value_type* s, size_type len, const allocator_type& a)
{
if (len <= maxSmallString)
{
flex_string_details::pod_copy(s, s + len, buf_);
buf_[maxSmallString] = value_type(maxSmallString - len);
}
else
{
new(buf_) Storage(s, len, a);
buf_[maxSmallString] = magic;
}
}
SmallStringOpt(size_type len, value_type c, const allocator_type& a)
{
if (len <= maxSmallString)
{
flex_string_details::pod_fill(buf_, buf_ + len, c);
buf_[maxSmallString] = value_type(maxSmallString - len);
}
else
{
new(buf_) Storage(len, c, a);
buf_[maxSmallString] = magic;
}
}
SmallStringOpt& operator=(const SmallStringOpt& rhs)
{
reserve(rhs.size());
resize(0, 0);
append(rhs.data(), rhs.size());
return *this;
}
~SmallStringOpt()
{
if (!Small()) GetStorage().~Storage();
}
iterator begin()
{
if (Small()) return buf_;
return &*GetStorage().begin();
}
const_iterator begin() const
{
if (Small()) return buf_;
return &*GetStorage().begin();
}
iterator end()
{
if (Small()) return buf_ + maxSmallString - buf_[maxSmallString];
return &*GetStorage().end();
}
const_iterator end() const
{
if (Small()) return buf_ + maxSmallString - buf_[maxSmallString];
return &*GetStorage().end();
}
size_type size() const
{
BOOST_ASSERT(!Small() || maxSmallString >= buf_[maxSmallString]);
return Small()
? maxSmallString - buf_[maxSmallString]
: GetStorage().size();
}
size_type max_size() const
{ return get_allocator().max_size(); }
size_type capacity() const
{ return Small() ? maxSmallString : GetStorage().capacity(); }
void reserve(size_type res_arg)
{
if (Small())
{
if (res_arg <= maxSmallString) return;
SmallStringOpt temp(*this);
this->~SmallStringOpt();
new(buf_) Storage(temp.data(), temp.size(),
temp.get_allocator());
buf_[maxSmallString] = magic;
GetStorage().reserve(res_arg);
}
else
{
GetStorage().reserve(res_arg);
}
BOOST_ASSERT(capacity() >= res_arg);
}
void append(const value_type* s, size_type sz)
{
if (!Small())
{
GetStorage().append(s, sz);
}
else
{
// append to a small string
const size_type neededCapacity =
maxSmallString - buf_[maxSmallString] + sz;
if (maxSmallString < neededCapacity)
{
// need to change storage strategy
allocator_type alloc;
Storage temp(alloc);
temp.reserve(neededCapacity);
temp.append(buf_, maxSmallString - buf_[maxSmallString]);
temp.append(s, sz);
buf_[maxSmallString] = magic;
new(buf_) Storage(temp.get_allocator());
GetStorage().swap(temp);
}
else
{
flex_string_details::pod_move(s, s + sz,
buf_ + maxSmallString - buf_[maxSmallString]);
buf_[maxSmallString] -= value_type(sz);
}
}
}
template <class InputIterator>
void append(InputIterator b, InputIterator e)
{
// @@@ todo: optimize this depending on iterator type
for (; b != e; ++b)
{
*this += *b;
}
}
void resize(size_type n, value_type c)
{
if (Small())
{
if (n > maxSmallString)
{
// Small string resized to big string
SmallStringOpt temp(*this); // can't throw
// 11-17-2001: correct exception safety bug
Storage newString(temp.data(), temp.size(),
temp.get_allocator());
newString.resize(n, c);
// We make the reasonable assumption that an empty Storage
// constructor won't throw
this->~SmallStringOpt();
new(&buf_[0]) Storage(temp.get_allocator());
buf_[maxSmallString] = value_type(magic);
GetStorage().swap(newString);
}
else
{
// Small string resized to small string
// 11-17-2001: bug fix: terminating zero not copied
size_type toFill = n > size() ? n - size() : 0;
flex_string_details::pod_fill(end(), end() + toFill, c);
buf_[maxSmallString] = value_type(maxSmallString - n);
}
}
else
{
if (n > maxSmallString)
{
// Big string resized to big string
GetStorage().resize(n, c);
}
else
{
// Big string resized to small string
// 11-17=2001: bug fix in the BOOST_ASSERTion below
BOOST_ASSERT(capacity() > n);
SmallStringOpt newObj(data(), n, get_allocator());
newObj.swap(*this);
}
}
}
void swap(SmallStringOpt& rhs)
{
if (Small())
{
if (rhs.Small())
{
// Small swapped with small
std::swap_ranges(buf_, buf_ + maxSmallString + 1,
rhs.buf_);
}
else
{
// Small swapped with big
// Make a copy of myself - can't throw
SmallStringOpt temp(*this);
// Nuke myself
this->~SmallStringOpt();
// Make an empty storage for myself (likely won't throw)
new(buf_) Storage(0, value_type(), rhs.get_allocator());
buf_[maxSmallString] = magic;
// Recurse to this same function
swap(rhs);
// Nuke rhs
rhs.~SmallStringOpt();
// Build the new small string into rhs
new(&rhs) SmallStringOpt(temp);
}
}
else
{
if (rhs.Small())
{
// Big swapped with small
// Already implemented, recurse with reversed args
rhs.swap(*this);
}
else
{
// Big swapped with big
GetStorage().swap(rhs.GetStorage());
}
}
}
const value_type* c_str() const
{
if (!Small()) return GetStorage().c_str();
buf_[maxSmallString - buf_[maxSmallString]] = value_type();
return buf_;
}
const value_type* data() const
{ return Small() ? buf_ : GetStorage().data(); }
allocator_type get_allocator() const
{ return allocator_type(); }
};
////////////////////////////////////////////////////////////////////////////////
// class template CowString
// Implements Copy on Write over any storage
////////////////////////////////////////////////////////////////////////////////
template <
typename Storage,
typename Align = BOOST_DEDUCED_TYPENAME Storage::value_type*
>
class CowString
{
typedef typename Storage::value_type E;
typedef typename flex_string_details::get_unsigned<E>::result RefCountType;
public:
typedef E value_type;
typedef typename Storage::iterator iterator;
typedef typename Storage::const_iterator const_iterator;
typedef typename Storage::allocator_type allocator_type;
typedef typename allocator_type::size_type size_type;
typedef typename Storage::reference reference;
private:
union
{
mutable char buf_[sizeof(Storage)];
Align align_;
};
Storage& Data() const
{
Storage* p = reinterpret_cast<Storage*>(&buf_[0]);
return *p;
}
RefCountType GetRefs() const
{
const Storage& d = Data();
BOOST_ASSERT(d.size() > 0);
BOOST_ASSERT(static_cast<RefCountType>(*d.begin()) != 0);
return *d.begin();
}
RefCountType& Refs()
{
Storage& d = Data();
BOOST_ASSERT(d.size() > 0);
return reinterpret_cast<RefCountType&>(*d.begin());
}
void MakeUnique() const
{
BOOST_ASSERT(GetRefs() >= 1);
if (GetRefs() == 1) return;
union
{
char buf_[sizeof(Storage)];
Align align_;
} temp;
--(*Data().begin()); // decrement the use count of the remaining object
Storage* p = reinterpret_cast<Storage*>(&temp.buf_[0]);
new(buf_) Storage(
*new(p) Storage(Data()),
flex_string_details::Shallow());
*Data().begin() = 1;
}
public:
CowString(const CowString& s)
{
if (s.GetRefs() == (std::numeric_limits<RefCountType>::max)())
{
// must make a brand new copy
new(buf_) Storage(s.Data()); // non shallow
Refs() = 1;
}
else
{
new(buf_) Storage(s.Data(), flex_string_details::Shallow());
++Refs();
}
BOOST_ASSERT(Data().size() > 0);
}
CowString(const allocator_type& a)
{
new(buf_) Storage(1, 1, a);
}
CowString(const E* s, size_type len, const allocator_type& a)
{
// Warning - MSVC's debugger has trouble tracing through the code below.
// It seems to be a const-correctness issue
//
new(buf_) Storage(a);
Data().reserve(len + 1);
Data().resize(1, 1);
Data().append(s, s + len);
}
CowString(size_type len, E c, const allocator_type& a)
{
new(buf_) Storage(len + 1, c, a);
Refs() = 1;
}
CowString& operator=(const CowString& rhs)
{
// CowString(rhs).swap(*this);
if (--Refs() == 0)
Data().~Storage();
if (rhs.GetRefs() == (std::numeric_limits<RefCountType>::max)())
{
// must make a brand new copy
new(buf_) Storage(rhs.Data()); // non shallow
Refs() = 1;
}
else
{
new(buf_) Storage(rhs.Data(), flex_string_details::Shallow());
++Refs();
}
BOOST_ASSERT(Data().size() > 0);
return *this;
}
~CowString()
{
BOOST_ASSERT(Data().size() > 0);
if (--Refs() == 0)
Data().~Storage();
}
iterator begin()
{
BOOST_ASSERT(Data().size() > 0);
MakeUnique();
return Data().begin() + 1;
}
const_iterator begin() const
{
BOOST_ASSERT(Data().size() > 0);
return Data().begin() + 1;
}
iterator end()
{
MakeUnique();
return Data().end();
}
const_iterator end() const
{
return Data().end();
}
size_type size() const
{
BOOST_ASSERT(Data().size() > 0);
return Data().size() - 1;
}
size_type max_size() const
{
BOOST_ASSERT(Data().max_size() > 0);
return Data().max_size() - 1;
}
size_type capacity() const
{
BOOST_ASSERT(Data().capacity() > 0);
return Data().capacity() - 1;
}
void resize(size_type n, E c)
{
BOOST_ASSERT(Data().size() > 0);
MakeUnique();
Data().resize(n + 1, c);
}
template <class FwdIterator>
void append(FwdIterator b, FwdIterator e)
{
MakeUnique();
Data().append(b, e);
}
void reserve(size_type res_arg)
{
if (capacity() > res_arg) return;
MakeUnique();
Data().reserve(res_arg + 1);
}
void swap(CowString& rhs)
{
Data().swap(rhs.Data());
}
const E* c_str() const
{
BOOST_ASSERT(Data().size() > 0);
return Data().c_str() + 1;
}
const E* data() const
{
BOOST_ASSERT(Data().size() > 0);
return Data().data() + 1;
}
allocator_type get_allocator() const
{
return Data().get_allocator();
}
};
////////////////////////////////////////////////////////////////////////////////
// class template flex_string
// a std::basic_string compatible implementation
// Uses a Storage policy
////////////////////////////////////////////////////////////////////////////////
template <typename E,
class T = std::char_traits<E>,
class A = std::allocator<E>,
class Storage = AllocatorStringStorage<E, A> >
class flex_string : private Storage
{
#if defined(BOOST_WAVE_FLEXSTRING_THROW_ON_ENFORCE)
template <typename Exception>
static void Enforce(bool condition, Exception*, const char* msg)
{ if (!condition) boost::throw_exception(Exception(msg)); }
#else
template <typename Exception>
static inline void Enforce(bool condition, Exception*, const char* msg)
{ BOOST_ASSERT(condition && msg); }
#endif // defined(BOOST_WAVE_FLEXSTRING_THROW_ON_ENFORCE)
#ifndef NDEBUG
bool Sane() const
{
return
begin() <= end() &&
empty() == (size() == 0) &&
empty() == (begin() == end()) &&
size() <= max_size() &&
capacity() <= max_size() &&
size() <= capacity();
}
struct Invariant;
friend struct Invariant;
struct Invariant
{
Invariant(const flex_string& s) : s_(s)
{
BOOST_ASSERT(s_.Sane());
}
~Invariant()
{
BOOST_ASSERT(s_.Sane());
}
private:
const flex_string& s_;
Invariant& operator=(const Invariant&);
};
#endif
public:
// types
typedef T traits_type;
typedef typename traits_type::char_type value_type;
typedef A allocator_type;
typedef typename A::size_type size_type;
typedef typename A::difference_type difference_type;
typedef typename A::reference reference;
typedef typename A::const_reference const_reference;
typedef typename A::pointer pointer;
typedef typename A::const_pointer const_pointer;
typedef typename Storage::iterator iterator;
typedef typename Storage::const_iterator const_iterator;
typedef boost::reverse_iterator<iterator> reverse_iterator;
typedef boost::reverse_iterator<const_iterator> const_reverse_iterator;
static const size_type npos; // = size_type(-1)
private:
static size_type Min(size_type lhs, size_type rhs)
{ return lhs < rhs ? lhs : rhs; }
static void Procust(size_type& n, size_type nmax)
{ if (n > nmax) n = nmax; }
public:
// 21.3.1 construct/copy/destroy
explicit flex_string(const A& a = A())
: Storage(a)
{}
flex_string(const flex_string& str)
: Storage(str)
{
}
flex_string(const flex_string& str, size_type pos,
size_type n = npos, const A& a = A())
: Storage(a)
{
Enforce(pos <= str.size(), (std::out_of_range*)0, "");
assign(str, pos, n);
}
flex_string(const value_type* s, const A& a = A())
: Storage(s, traits_type::length(s), a)
{}
flex_string(const value_type* s, size_type n, const A& a = A())
: Storage(s, n, a)
{}
flex_string(size_type n, value_type c, const A& a = A())
: Storage(n, c, a)
{}
template <class InputIterator>
flex_string(InputIterator begin, InputIterator end, const A& a = A())
: Storage(a)
{
assign(begin, end);
}
~flex_string()
{}
flex_string& operator=(const flex_string& str)
{
if (this != &str) {
Storage& s = *this;
s = str;
}
return *this;
}
flex_string& operator=(const value_type* s)
{
assign(s);
return *this;
}
flex_string& operator=(value_type c)
{
assign(1, c);
return *this;
}
// 21.3.2 iterators:
iterator begin()
{ return Storage::begin(); }
const_iterator begin() const
{ return Storage::begin(); }
iterator end()
{ return Storage::end(); }
const_iterator end() const
{ return Storage::end(); }
reverse_iterator rbegin()
{ return reverse_iterator(end()); }
const_reverse_iterator rbegin() const
{ return const_reverse_iterator(end()); }
reverse_iterator rend()
{ return reverse_iterator(begin()); }
const_reverse_iterator rend() const
{ return const_reverse_iterator(begin()); }
#if BOOST_WAVE_FLEX_STRING_SERIALIZATION_HACK != 0
// temporary hack to make it easier to serialize flex_string's using
// the Boost.Serialization library
value_type & back() { return *(begin()+size()-1); }
value_type const& back() const { return *(begin()+size()-1); }
#endif
// 21.3.3 capacity:
size_type size() const
{ return Storage::size(); }
size_type length() const
{ return size(); }
size_type max_size() const
{ return Storage::max_size(); }
void resize(size_type n, value_type c)
{ Storage::resize(n, c); }
void resize(size_type n)
{ resize(n, value_type()); }
size_type capacity() const
{ return Storage::capacity(); }
void reserve(size_type res_arg = 0)
{
Enforce(res_arg <= max_size(), (std::length_error*)0, "");
Storage::reserve(res_arg);
}
void clear()
{ resize(0); }
bool empty() const
{ return size() == 0; }
// 21.3.4 element access:
const_reference operator[](size_type pos) const
{ return *(begin() + pos); }
reference operator[](size_type pos)
{ return *(begin() + pos); }
const_reference at(size_type n) const
{
Enforce(n < size(), (std::out_of_range*)0, "");
return (*this)[n];
}
reference at(size_type n)
{
Enforce(n < size(), (std::out_of_range*)0, "");
return (*this)[n];
}
// 21.3.5 modifiers:
flex_string& operator+=(const flex_string& str)
{ return append(str); }
flex_string& operator+=(const value_type* s)
{ return append(s); }
flex_string& operator+=(value_type c)
{
push_back(c);
return *this;
}
flex_string& append(const flex_string& str)
{ return append(str, 0, npos); }
flex_string& append(const flex_string& str, const size_type pos,
size_type n)
{
const size_type sz = str.size();
Enforce(pos <= sz, (std::out_of_range*)0, "");
Procust(n, sz - pos);
return append(str.c_str() + pos, n);
}
flex_string& append(const value_type* s, const size_type n)
{
#ifndef NDEBUG
Invariant checker(*this);
#endif
if (IsAliasedRange(s, s + n))
{
const size_type offset = s - &*begin();
Storage::reserve(size() + n);
s = &*begin() + offset;
}
Storage::append(s, s+ n);
return *this;
}
flex_string& append(const value_type* s)
{ return append(s, traits_type::length(s)); }
flex_string& append(size_type n, value_type c)
{
resize(size() + n, c);
return *this;
}
template<class InputIterator>
flex_string& append(InputIterator first, InputIterator last)
{
insert(end(), first, last);
return *this;
}
void push_back(value_type c)
{
const size_type cap = capacity();
if (size() == cap)
{
reserve(cap << 1u);
}
Storage::append(&c, &c + 1);
}
flex_string& assign(const flex_string& str)
{
if (&str == this) return *this;
return assign(str.data(), str.size());
}
flex_string& assign(const flex_string& str, size_type pos,
size_type n)
{
const size_type sz = str.size();
Enforce(pos <= str.size(), (std::out_of_range*)0, "");
Procust(n, sz - pos);
return assign(str.data() + pos, n);
}
flex_string& assign(const value_type* s, size_type n)
{
#ifndef NDEBUG
Invariant checker(*this);
#endif
if (size() >= n)
{
std::copy(s, s + n, begin());
resize(n);
}
else
{
const value_type *const s2 = s + size();
std::copy(s, s2, begin());
append(s2, n - size());
}
return *this;
}
flex_string& assign(const value_type* s)
{ return assign(s, traits_type::length(s)); }
template <class ItOrLength, class ItOrChar>
flex_string& assign(ItOrLength first_or_n, ItOrChar last_or_c)
{ return replace(begin(), end(), first_or_n, last_or_c); }
flex_string& insert(size_type pos1, const flex_string& str)
{ return insert(pos1, str.data(), str.size()); }
flex_string& insert(size_type pos1, const flex_string& str,
size_type pos2, size_type n)
{
Enforce(pos2 <= str.length(), (std::out_of_range*)0, "");
Procust(n, str.length() - pos2);
return insert(pos1, str.data() + pos2, n);
}
flex_string& insert(size_type pos, const value_type* s, size_type n)
{
Enforce(pos <= length(), (std::out_of_range*)0, "");
insert(begin() + pos, s, s + n);
return *this;
}
flex_string& insert(size_type pos, const value_type* s)
{ return insert(pos, s, traits_type::length(s)); }
flex_string& insert(size_type pos, size_type n, value_type c)
{
Enforce(pos <= length(), (std::out_of_range*)0, "");
insert(begin() + pos, n, c);
return *this;
}
iterator insert(iterator p, value_type c = value_type())
{
const size_type pos = p - begin();
insert(pos, &c, 1);
return begin() + pos;
}
private:
// Care must be taken when dereferencing some iterator types.
//
// Users can implement this function in their namespace if their storage
// uses a special iterator type, the function will be found through ADL.
template<class Iterator>
const typename std::iterator_traits<Iterator>::value_type*
DereferenceValidIterator(Iterator it) const
{
return &*it;
}
// Care must be taken when dereferencing a reverse iterators, hence this
// special case. This isn't in the std namespace so as not to pollute it or
// create name clashes.
template<typename Iterator>
const typename std::iterator_traits<Iterator>::value_type*
DereferenceValidIterator(std::reverse_iterator<Iterator> it) const
{
return &*--it;
}
// Determine if the range aliases the current string.
//
// This method cannot be const because calling begin/end on copy-on-write
// implementations must have side effects.
// A const version wouldn't make the string unique through this call.
template<class Iterator>
bool IsAliasedRange(Iterator beginIterator, Iterator endIterator)
{
if(!empty() && beginIterator != endIterator)
{
typedef const typename std::iterator_traits<Iterator>::value_type *
pointer;
pointer myBegin(&*begin());
pointer myEnd(&*begin() + size());
pointer rangeBegin(DereferenceValidIterator(beginIterator));
const std::less_equal<pointer> less_equal = std::less_equal<pointer>();
if(less_equal(myBegin, rangeBegin) && less_equal(rangeBegin, myEnd))
return true;
}
return false;
}
template <int i> class Selector {};
flex_string& InsertImplDiscr(iterator p,
size_type n, value_type c, Selector<1>)
{
#ifndef NDEBUG
Invariant checker(*this);
#endif
BOOST_ASSERT(begin() <= p && p <= end());
const size_type insertOffset(p - begin());
const size_type originalSize(size());
if(n < originalSize - insertOffset)
{
// The new characters fit within the original string.
// The characters that are pushed back need to be moved because
// they're aliased.
// The appended characters will all be overwritten by the move.
append(n, value_type(0));
value_type* begin(&*begin());
flex_string_details::pod_move(begin + insertOffset,
begin + originalSize, begin + insertOffset + n);
std::fill(begin + insertOffset, begin + insertOffset + n, c);
}
else
{
// The new characters exceed the original string.
// The characters that are pushed back can simply be copied since
// they aren't aliased.
// The appended characters will partly be overwritten by the copy.
append(n, c);
value_type* begin(&*begin());
flex_string_details::pod_copy(begin + insertOffset,
begin + originalSize, begin + insertOffset + n);
std::fill(begin + insertOffset, begin + originalSize, c);
}
return *this;
}
template<class InputIterator>
flex_string& InsertImplDiscr(iterator i,
InputIterator b, InputIterator e, Selector<0>)
{
InsertImpl(i, b, e,
typename std::iterator_traits<InputIterator>::iterator_category());
return *this;
}
template <class FwdIterator>
void InsertImpl(iterator i,
FwdIterator s1, FwdIterator s2, std::forward_iterator_tag)
{
if(s1 == s2)
{
// Insert an empty range.
return;
}
if(IsAliasedRange(s1, s2))
{
// The source range is contained in the current string, copy it
// and recurse.
const flex_string temporary(s1, s2);
InsertImpl(i, temporary.begin(), temporary.end(),
typename std::iterator_traits<FwdIterator>::iterator_category());
return;
}
#ifndef NDEBUG
Invariant checker(*this);
#endif
const size_type pos = i - begin();
const typename std::iterator_traits<FwdIterator>::difference_type n2 =
std::distance(s1, s2);
BOOST_ASSERT(n2 >= 0);
using namespace flex_string_details;
BOOST_ASSERT(pos <= size());
const typename std::iterator_traits<FwdIterator>::difference_type maxn2 =
capacity() - size();
if (maxn2 < n2)
{
// Reallocate the string.
BOOST_ASSERT(!IsAliasedRange(s1, s2));
reserve(size() + n2);
i = begin() + pos;
}
if (pos + n2 <= size())
{
const iterator tailBegin = end() - n2;
Storage::append(tailBegin, tailBegin + n2);
std::copy(reverse_iterator(tailBegin), reverse_iterator(i),
reverse_iterator(tailBegin + n2));
std::copy(s1, s2, i);
}
else
{
FwdIterator t = s1;
const size_type old_size = size();
std::advance(t, old_size - pos);
BOOST_ASSERT(std::distance(t, s2) >= 0);
Storage::append(t, s2);
Storage::append(data() + pos, data() + old_size);
std::copy(s1, t, i);
}
}
template <class InputIterator>
void InsertImpl(iterator insertPosition,
InputIterator inputBegin, InputIterator inputEnd,
std::input_iterator_tag)
{
flex_string temporary(begin(), insertPosition);
for (; inputBegin != inputEnd; ++inputBegin)
{
temporary.push_back(*inputBegin);
}
temporary.append(insertPosition, end());
swap(temporary);
}
public:
template <class ItOrLength, class ItOrChar>
void insert(iterator p, ItOrLength first_or_n, ItOrChar last_or_c)
{
Selector<std::numeric_limits<ItOrLength>::is_specialized> sel;
InsertImplDiscr(p, first_or_n, last_or_c, sel);
}
flex_string& erase(size_type pos = 0, size_type n = npos)
{
#ifndef NDEBUG
Invariant checker(*this);
#endif
Enforce(pos <= length(), (std::out_of_range*)0, "");
Procust(n, length() - pos);
std::copy(begin() + pos + n, end(), begin() + pos);
resize(length() - n);
return *this;
}
iterator erase(iterator position)
{
const size_type pos(position - begin());
erase(pos, 1);
return begin() + pos;
}
iterator erase(iterator first, iterator last)
{
const size_type pos(first - begin());
erase(pos, last - first);
return begin() + pos;
}
// Replaces at most n1 chars of *this, starting with pos1 with the content of str
flex_string& replace(size_type pos1, size_type n1, const flex_string& str)
{ return replace(pos1, n1, str, 0, npos); }
// Replaces at most n1 chars of *this, starting with pos1,
// with at most n2 chars of str starting with pos2
flex_string& replace(size_type pos1, size_type n1, const flex_string& str,
size_type pos2, size_type n2)
{
Enforce(pos2 <= str.length(), (std::out_of_range*)0, "");
return replace(pos1, n1, str.data() + pos2,
Min(n2, str.size() - pos2));
}
// Replaces at most n1 chars of *this, starting with pos, with chars from s
flex_string& replace(size_type pos, size_type n1, const value_type* s)
{ return replace(pos, n1, s, traits_type::length(s)); }
// Replaces at most n1 chars of *this, starting with pos, with n2 occurences of c
// consolidated with
// Replaces at most n1 chars of *this, starting with pos,
// with at most n2 chars of str.
// str must have at least n2 chars.
template <class StrOrLength, class NumOrChar>
flex_string& replace(size_type pos, size_type n1,
StrOrLength s_or_n2, NumOrChar n_or_c)
{
#ifndef NDEBUG
Invariant checker(*this);
#endif
Enforce(pos <= size(), (std::out_of_range*)0, "");
Procust(n1, length() - pos);
const iterator b = begin() + pos;
return replace(b, b + n1, s_or_n2, n_or_c);
}
flex_string& replace(iterator i1, iterator i2, const flex_string& str)
{ return replace(i1, i2, str.c_str(), str.length()); }
flex_string& replace(iterator i1, iterator i2, const value_type* s)
{ return replace(i1, i2, s, traits_type::length(s)); }
private:
flex_string& ReplaceImplDiscr(iterator i1, iterator i2,
const value_type* s, size_type n, Selector<2>)
{
BOOST_ASSERT(i1 <= i2);
BOOST_ASSERT(begin() <= i1 && i1 <= end());
BOOST_ASSERT(begin() <= i2 && i2 <= end());
return replace(i1, i2, s, s + n);
}
flex_string& ReplaceImplDiscr(iterator i1, iterator i2,
size_type n2, value_type c, Selector<1>)
{
const size_type n1 = i2 - i1;
if (n1 > n2)
{
std::fill(i1, i1 + n2, c);
erase(i1 + n2, i2);
}
else
{
std::fill(i1, i2, c);
insert(i2, n2 - n1, c);
}
return *this;
}
template <class InputIterator>
flex_string& ReplaceImplDiscr(iterator i1, iterator i2,
InputIterator b, InputIterator e, Selector<0>)
{
ReplaceImpl(i1, i2, b, e,
typename std::iterator_traits<InputIterator>::iterator_category());
return *this;
}
template <class FwdIterator>
void ReplaceImpl(iterator i1, iterator i2,
FwdIterator s1, FwdIterator s2, std::forward_iterator_tag)
{
#ifndef NDEBUG
Invariant checker(*this);
#endif
const typename std::iterator_traits<iterator>::difference_type n1 =
i2 - i1;
BOOST_ASSERT(n1 >= 0);
const typename std::iterator_traits<FwdIterator>::difference_type n2 =
std::distance(s1, s2);
BOOST_ASSERT(n2 >= 0);
if (IsAliasedRange(s1, s2))
{
// Aliased replace, copy to new string.
flex_string temporary;
temporary.reserve(size() - n1 + n2);
temporary.append(begin(), i1).append(s1, s2).append(i2, end());
swap(temporary);
return;
}
if (n1 > n2)
{
// Shrinks
std::copy(s1, s2, i1);
erase(i1 + n2, i2);
}
else
{
// Grows
flex_string_details::copy_n(s1, n1, i1);
std::advance(s1, n1);
insert(i2, s1, s2);
}
}
template <class InputIterator>
void ReplaceImpl(iterator i1, iterator i2,
InputIterator b, InputIterator e, std::input_iterator_tag)
{
flex_string temp(begin(), i1);
temp.append(b, e).append(i2, end());
swap(temp);
}
public:
template <class T1, class T2>
flex_string& replace(iterator i1, iterator i2,
T1 first_or_n_or_s, T2 last_or_c_or_n)
{
const bool
num1 = std::numeric_limits<T1>::is_specialized,
num2 = std::numeric_limits<T2>::is_specialized;
return ReplaceImplDiscr(i1, i2, first_or_n_or_s, last_or_c_or_n,
Selector<num1 ? (num2 ? 1 : -1) : (num2 ? 2 : 0)>());
}
size_type copy(value_type* s, size_type n, size_type pos = 0) const
{
Enforce(pos <= size(), (std::out_of_range*)0, "");
n = Min(n, size() - pos);
flex_string_details::pod_copy(
&*begin() + pos,
&*begin() + pos + n,
s);
return n;
}
void swap(flex_string& rhs)
{
Storage& srhs = rhs;
this->Storage::swap(srhs);
}
// 21.3.6 string operations:
const value_type* c_str() const
{ return Storage::c_str(); }
const value_type* data() const
{ return Storage::data(); }
allocator_type get_allocator() const
{ return Storage::get_allocator(); }
size_type find(const flex_string& str, size_type pos = 0) const
{ return find(str.data(), pos, str.length()); }
size_type find (const value_type* s, size_type pos, size_type n) const
{
const size_type size_(size());
if (n + pos > size_)
return npos;
for (; pos < size_; ++pos)
{
if (traits_type::compare(&*begin() + pos, s, n) == 0)
{
return pos;
}
}
return npos;
}
size_type find (const value_type* s, size_type pos = 0) const
{ return find(s, pos, traits_type::length(s)); }
size_type find (value_type c, size_type pos = 0) const
{ return find(&c, pos, 1); }
size_type rfind(const flex_string& str, size_type pos = npos) const
{ return rfind(str.c_str(), pos, str.length()); }
size_type rfind(const value_type* s, size_type pos, size_type n) const
{
if (n > length()) return npos;
pos = Min(pos, length() - n);
if (n == 0) return pos;
const_iterator i(begin() + pos);
for (; ; --i)
{
if (traits_type::eq(*i, *s)
&& traits_type::compare(&*i, s, n) == 0)
{
return i - begin();
}
if (i == begin()) break;
}
return npos;
}
size_type rfind(const value_type* s, size_type pos = npos) const
{ return rfind(s, pos, traits_type::length(s)); }
size_type rfind(value_type c, size_type pos = npos) const
{ return rfind(&c, pos, 1); }
size_type find_first_of(const flex_string& str, size_type pos = 0) const
{ return find_first_of(str.c_str(), pos, str.length()); }
size_type find_first_of(const value_type* s,
size_type pos, size_type n) const
{
if (pos > length() || n == 0) return npos;
const_iterator i(begin() + pos),
finish(end());
for (; i != finish; ++i)
{
if (traits_type::find(s, n, *i) != 0)
{
return i - begin();
}
}
return npos;
}
size_type find_first_of(const value_type* s, size_type pos = 0) const
{ return find_first_of(s, pos, traits_type::length(s)); }
size_type find_first_of(value_type c, size_type pos = 0) const
{ return find_first_of(&c, pos, 1); }
size_type find_last_of (const flex_string& str,
size_type pos = npos) const
{ return find_last_of(str.c_str(), pos, str.length()); }
size_type find_last_of (const value_type* s, size_type pos,
size_type n) const
{
if (!empty() && n > 0)
{
pos = Min(pos, length() - 1);
const_iterator i(begin() + pos);
for (;; --i)
{
if (traits_type::find(s, n, *i) != 0)
{
return i - begin();
}
if (i == begin()) break;
}
}
return npos;
}
size_type find_last_of (const value_type* s,
size_type pos = npos) const
{ return find_last_of(s, pos, traits_type::length(s)); }
size_type find_last_of (value_type c, size_type pos = npos) const
{ return find_last_of(&c, pos, 1); }
size_type find_first_not_of(const flex_string& str,
size_type pos = 0) const
{ return find_first_not_of(str.data(), pos, str.size()); }
size_type find_first_not_of(const value_type* s, size_type pos,
size_type n) const
{
if (pos < length())
{
const_iterator
i(begin() + pos),
finish(end());
for (; i != finish; ++i)
{
if (traits_type::find(s, n, *i) == 0)
{
return i - begin();
}
}
}
return npos;
}
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)); }
size_type find_first_not_of(value_type c, size_type pos = 0) const
{ return find_first_not_of(&c, pos, 1); }
size_type find_last_not_of(const flex_string& str,
size_type pos = npos) const
{ return find_last_not_of(str.c_str(), pos, str.length()); }
size_type find_last_not_of(const value_type* s, size_type pos,
size_type n) const
{
if (!empty())
{
pos = Min(pos, size() - 1);
const_iterator i(begin() + pos);
for (;; --i)
{
if (traits_type::find(s, n, *i) == 0)
{
return i - begin();
}
if (i == begin()) break;
}
}
return npos;
}
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)); }
size_type find_last_not_of (value_type c, size_type pos = npos) const
{ return find_last_not_of(&c, pos, 1); }
flex_string substr(size_type pos = 0, size_type n = npos) const
{
Enforce(pos <= size(), (std::out_of_range*)0, "");
return flex_string(data() + pos, Min(n, size() - pos));
}
std::ptrdiff_t compare(const flex_string& str) const
{
// FIX due to Goncalo N M de Carvalho July 18, 2005
return compare(0, size(), str);
}
std::ptrdiff_t compare(size_type pos1, size_type n1,
const flex_string& str) const
{ return compare(pos1, n1, str.data(), str.size()); }
// FIX to compare: added the TC
// (http://www.comeaucomputing.com/iso/lwg-defects.html number 5)
// Thanks to Caleb Epstein for the fix
std::ptrdiff_t compare(size_type pos1, size_type n1,
const value_type* s) const
{
return compare(pos1, n1, s, traits_type::length(s));
}
std::ptrdiff_t compare(size_type pos1, size_type n1,
const value_type* s, size_type n2) const
{
Enforce(pos1 <= size(), (std::out_of_range*)0, "");
Procust(n1, size() - pos1);
const int r = traits_type::compare(pos1 + data(), s, Min(n1, n2));
return r != 0 ? r : n1 > n2 ? 1 : n1 < n2 ? -1 : 0;
}
std::ptrdiff_t compare(size_type pos1, size_type n1,
const flex_string& str,
size_type pos2, size_type n2) const
{
Enforce(pos2 <= str.size(), (std::out_of_range*)0, "");
return compare(pos1, n1, str.data() + pos2, Min(n2, str.size() - pos2));
}
std::ptrdiff_t compare(const value_type* s) const
{
// Could forward to compare(0, size(), s, traits_type::length(s))
// but that does two extra checks
const size_type n1(size()), n2(traits_type::length(s));
const int r = traits_type::compare(data(), s, Min(n1, n2));
return r != 0 ? r : n1 > n2 ? 1 : n1 < n2 ? -1 : 0;
}
};
// non-member functions
template <typename E, class T, class A, class S>
flex_string<E, T, A, S> operator+(const flex_string<E, T, A, S>& lhs,
const flex_string<E, T, A, S>& rhs)
{
flex_string<E, T, A, S> result;
result.reserve(lhs.size() + rhs.size());
result.append(lhs).append(rhs);
return result;
}
template <typename E, class T, class A, class S>
flex_string<E, T, A, S> operator+(const typename flex_string<E, T, A, S>::value_type* lhs,
const flex_string<E, T, A, S>& rhs)
{
flex_string<E, T, A, S> result;
const typename flex_string<E, T, A, S>::size_type len =
flex_string<E, T, A, S>::traits_type::length(lhs);
result.reserve(len + rhs.size());
result.append(lhs, len).append(rhs);
return result;
}
template <typename E, class T, class A, class S>
flex_string<E, T, A, S> operator+(
typename flex_string<E, T, A, S>::value_type lhs,
const flex_string<E, T, A, S>& rhs)
{
flex_string<E, T, A, S> result;
result.reserve(1 + rhs.size());
result.push_back(lhs);
result.append(rhs);
return result;
}
template <typename E, class T, class A, class S>
flex_string<E, T, A, S> operator+(const flex_string<E, T, A, S>& lhs,
const typename flex_string<E, T, A, S>::value_type* rhs)
{
typedef typename flex_string<E, T, A, S>::size_type size_type;
typedef typename flex_string<E, T, A, S>::traits_type traits_type;
flex_string<E, T, A, S> result;
const size_type len = traits_type::length(rhs);
result.reserve(lhs.size() + len);
result.append(lhs).append(rhs, len);
return result;
}
template <typename E, class T, class A, class S>
flex_string<E, T, A, S> operator+(const flex_string<E, T, A, S>& lhs,
typename flex_string<E, T, A, S>::value_type rhs)
{
flex_string<E, T, A, S> result;
result.reserve(lhs.size() + 1);
result.append(lhs);
result.push_back(rhs);
return result;
}
template <typename E, class T, class A, class S>
inline bool operator==(const flex_string<E, T, A, S>& lhs,
const flex_string<E, T, A, S>& rhs)
{ return lhs.compare(rhs) == 0; }
template <typename E, class T, class A, class S>
inline bool operator==(const typename flex_string<E, T, A, S>::value_type* lhs,
const flex_string<E, T, A, S>& rhs)
{ return rhs == lhs; }
template <typename E, class T, class A, class S>
inline bool operator==(const flex_string<E, T, A, S>& lhs,
const typename flex_string<E, T, A, S>::value_type* rhs)
{ return lhs.compare(rhs) == 0; }
template <typename E, class T, class A, class S>
inline bool operator!=(const flex_string<E, T, A, S>& lhs,
const flex_string<E, T, A, S>& rhs)
{ return !(lhs == rhs); }
template <typename E, class T, class A, class S>
inline bool operator!=(const typename flex_string<E, T, A, S>::value_type* lhs,
const flex_string<E, T, A, S>& rhs)
{ return !(lhs == rhs); }
template <typename E, class T, class A, class S>
inline bool operator!=(const flex_string<E, T, A, S>& lhs,
const typename flex_string<E, T, A, S>::value_type* rhs)
{ return !(lhs == rhs); }
template <typename E, class T, class A, class S>
inline bool operator<(const flex_string<E, T, A, S>& lhs,
const flex_string<E, T, A, S>& rhs)
{ return lhs.compare(rhs) < 0; }
template <typename E, class T, class A, class S>
inline bool operator<(const flex_string<E, T, A, S>& lhs,
const typename flex_string<E, T, A, S>::value_type* rhs)
{ return lhs.compare(rhs) < 0; }
template <typename E, class T, class A, class S>
inline bool operator<(const typename flex_string<E, T, A, S>::value_type* lhs,
const flex_string<E, T, A, S>& rhs)
{ return rhs.compare(lhs) > 0; }
template <typename E, class T, class A, class S>
inline bool operator>(const flex_string<E, T, A, S>& lhs,
const flex_string<E, T, A, S>& rhs)
{ return rhs < lhs; }
template <typename E, class T, class A, class S>
inline bool operator>(const flex_string<E, T, A, S>& lhs,
const typename flex_string<E, T, A, S>::value_type* rhs)
{ return rhs < lhs; }
template <typename E, class T, class A, class S>
bool operator>(const typename flex_string<E, T, A, S>::value_type* lhs,
const flex_string<E, T, A, S>& rhs)
{ return rhs < lhs; }
template <typename E, class T, class A, class S>
inline bool operator<=(const flex_string<E, T, A, S>& lhs,
const flex_string<E, T, A, S>& rhs)
{ return !(rhs < lhs); }
template <typename E, class T, class A, class S>
inline bool operator<=(const flex_string<E, T, A, S>& lhs,
const typename flex_string<E, T, A, S>::value_type* rhs)
{ return !(rhs < lhs); }
template <typename E, class T, class A, class S>
bool operator<=(const typename flex_string<E, T, A, S>::value_type* lhs,
const flex_string<E, T, A, S>& rhs)
{ return !(rhs < lhs); }
template <typename E, class T, class A, class S>
bool operator>=(const flex_string<E, T, A, S>& lhs,
const flex_string<E, T, A, S>& rhs)
{ return !(lhs < rhs); }
template <typename E, class T, class A, class S>
bool operator>=(const flex_string<E, T, A, S>& lhs,
const typename flex_string<E, T, A, S>::value_type* rhs)
{ return !(lhs < rhs); }
template <typename E, class T, class A, class S>
inline bool operator>=(const typename flex_string<E, T, A, S>::value_type* lhs,
const flex_string<E, T, A, S>& rhs)
{ return !(lhs < rhs); }
template <typename E, class T, class A, class S>
void swap(flex_string<E, T, A, S>& lhs, flex_string<E, T, A, S>& rhs)
{
// subclause 21.3.7.8:
lhs.swap(rhs);
}
template <typename E, class T, class A, class S>
inline std::basic_istream<typename flex_string<E, T, A, S>::value_type,
typename flex_string<E, T, A, S>::traits_type>&
operator>>(
std::basic_istream<typename flex_string<E, T, A, S>::value_type,
typename flex_string<E, T, A, S>::traits_type>& is,
flex_string<E, T, A, S>& str);
template <typename E, class T, class A, class S>
std::basic_ostream<typename flex_string<E, T, A, S>::value_type,
typename flex_string<E, T, A, S>::traits_type>&
operator<<(
std::basic_ostream<typename flex_string<E, T, A, S>::value_type,
typename flex_string<E, T, A, S>::traits_type>& os,
const flex_string<E, T, A, S>& str)
{ return os << str.c_str(); }
// The getline below implementations are from the SGI STL (http://www.sgi.com/tech/stl/)
// and come with the following copyright:
//
// Permission to use, copy, modify, distribute and sell this software and its
// documentation for any purpose is hereby granted without fee, provided that
// the below copyright notice appears in all copies and that both the copyright
// notice and this permission notice appear in supporting documentation. Silicon
// Graphics makes no representations about the suitability of this software for
// any purpose. It is provided "as is" without express or implied warranty.
//
// Copyright (c) 1997-1999
// Silicon Graphics Computer Systems, Inc.
//
// Copyright (c) 1994
// Hewlett-Packard Company
template <typename E, class T, class A, class S>
std::basic_istream<typename flex_string<E, T, A, S>::value_type,
typename flex_string<E, T, A, S>::traits_type>&
getline(
std::basic_istream<typename flex_string<E, T, A, S>::value_type,
typename flex_string<E, T, A, S>::traits_type>& is,
flex_string<E, T, A, S>& str,
typename flex_string<E, T, A, S>::value_type delim)
{
size_t nread = 0;
typename std::basic_istream<typename flex_string<E, T, A, S>::value_type,
typename flex_string<E, T, A, S>::traits_type>::sentry sentry(is, true);
if (sentry) {
std::basic_streambuf<typename flex_string<E, T, A, S>::value_type,
typename flex_string<E, T, A, S>::traits_type>* buf = is.rdbuf();
str.clear();
while (nread < str.max_size()) {
int c1 = buf->sbumpc();
if (flex_string<E, T, A, S>::traits_type::eq_int_type(c1,
flex_string<E, T, A, S>::traits_type::eof()))
{
is.setstate(std::ios_base::eofbit);
break;
}
else {
++nread;
typename flex_string<E, T, A, S>::value_type c =
flex_string<E, T, A, S>::traits_type::to_char_type(c1);
if (!flex_string<E, T, A, S>::traits_type::eq(c, delim))
str.push_back(c);
else
break; // Character is extracted but not appended.
}
}
}
if (nread == 0 || nread >= str.max_size())
is.setstate(std::ios_base::failbit);
return is;
}
template <typename E, class T, class A, class S>
std::basic_istream<typename flex_string<E, T, A, S>::value_type,
typename flex_string<E, T, A, S>::traits_type>&
getline(
std::basic_istream<typename flex_string<E, T, A, S>::value_type,
typename flex_string<E, T, A, S>::traits_type>& is,
flex_string<E, T, A, S>& str)
{
return getline(is, str, is.widen('\n'));
}
template <typename E1, class T, class A, class S>
const typename flex_string<E1, T, A, S>::size_type
flex_string<E1, T, A, S>::npos = (typename flex_string<E1, T, A, S>::size_type)(-1);
///////////////////////////////////////////////////////////////////////////////
} // namespace util
} // namespace wave
} // namespace boost
#if BOOST_WAVE_SERIALIZATION != 0
///////////////////////////////////////////////////////////////////////////////
namespace boost { namespace serialization {
#if !defined(BOOST_WAVE_FLEX_STRING_SERIALIZATION_HACK)
// FIXME: This doesn't work because of the missing flex_string::operator>>()
template <typename E, class T, class A, class S>
struct implementation_level<boost::wave::util::flex_string<E, T, A, S> >
{
typedef mpl::integral_c_tag tag;
typedef mpl::int_<boost::serialization::primitive_type> type;
BOOST_STATIC_CONSTANT(
int,
value = implementation_level::type::value
);
};
#else
// We serialize flex_strings as vectors of char's for now
template<class Archive, typename E, class T, class A, class S>
inline void save(Archive & ar,
boost::wave::util::flex_string<E, T, A, S> const &t,
const unsigned int file_version)
{
boost::serialization::stl::save_collection<
Archive, wave::util::flex_string<E, T, A, S> >(ar, t);
}
template<class Archive, typename E, class T, class A, class S>
inline void load(Archive & ar, boost::wave::util::flex_string<E, T, A, S> &t,
const unsigned int file_version)
{
boost::serialization::stl::load_collection<
Archive, boost::wave::util::flex_string<E, T, A, S>,
boost::serialization::stl::archive_input_seq<
Archive, boost::wave::util::flex_string<E, T, A, S> >,
boost::serialization::stl::reserve_imp<
boost::wave::util::flex_string<E, T, A, S> >
>(ar, t);
}
// split non-intrusive serialization function member into separate
// non intrusive save/load member functions
template<class Archive, typename E, class T, class A, class S>
inline void serialize(Archive & ar, boost::wave::util::flex_string<E, T, A, S> &t,
const unsigned int file_version)
{
boost::serialization::split_free(ar, t, file_version);
}
#endif
///////////////////////////////////////////////////////////////////////////////
}} // boost::serialization
#endif
// the suffix header occurs after all of the code
#ifdef BOOST_HAS_ABI_HEADERS
#include BOOST_ABI_SUFFIX
#endif
#endif // FLEX_STRING_INC_