CMake/Source/cmAlgorithms.h

/*============================================================================
  CMake - Cross Platform Makefile Generator
  Copyright 2015 Stephen Kelly <steveire@gmail.com>

  Distributed under the OSI-approved BSD License (the "License");
  see accompanying file Copyright.txt for details.

  This software is distributed WITHOUT ANY WARRANTY; without even the
  implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.
  See the License for more information.
============================================================================*/
#ifndef cmAlgorithms_h
#define cmAlgorithms_h

#include "cmStandardIncludes.h"

inline bool cmHasLiteralPrefixImpl(const std::string &str1,
                                 const char *str2,
                                 size_t N)
{
  return strncmp(str1.c_str(), str2, N) == 0;
}

inline bool cmHasLiteralPrefixImpl(const char* str1,
                                 const char *str2,
                                 size_t N)
{
  return strncmp(str1, str2, N) == 0;
}

inline bool cmHasLiteralSuffixImpl(const std::string &str1,
                                   const char *str2,
                                   size_t N)
{
  size_t len = str1.size();
  return len >= N && strcmp(str1.c_str() + len - N, str2) == 0;
}

inline bool cmHasLiteralSuffixImpl(const char* str1,
                                   const char* str2,
                                   size_t N)
{
  size_t len = strlen(str1);
  return len >= N && strcmp(str1 + len - N, str2) == 0;
}

template<typename T, size_t N>
const T* cmArrayBegin(const T (&a)[N]) { return a; }
template<typename T, size_t N>
const T* cmArrayEnd(const T (&a)[N]) { return a + N; }
template<typename T, size_t N>
size_t cmArraySize(const T (&)[N]) { return N; }

template<typename T, size_t N>
bool cmHasLiteralPrefix(T str1, const char (&str2)[N])
{
  return cmHasLiteralPrefixImpl(str1, str2, N - 1);
}

template<typename T, size_t N>
bool cmHasLiteralSuffix(T str1, const char (&str2)[N])
{
  return cmHasLiteralSuffixImpl(str1, str2, N - 1);
}

struct cmStrCmp {
  cmStrCmp(const char *test) : m_test(test) {}
  cmStrCmp(const std::string &test) : m_test(test) {}

  bool operator()(const std::string& input) const
  {
    return m_test == input;
  }

  bool operator()(const char * input) const
  {
    return strcmp(input, m_test.c_str()) == 0;
  }

private:
  const std::string m_test;
};

namespace ContainerAlgorithms {

template<typename T>
struct cmIsPair
{
  enum { value = false };
};

template<typename K, typename V>
struct cmIsPair<std::pair<K, V> >
{
  enum { value = true };
};

template<typename Container,
    bool valueTypeIsPair = cmIsPair<typename Container::value_type>::value>
struct DefaultDeleter
{
  void operator()(typename Container::value_type value) {
    delete value;
  }
};

template<typename Container>
struct DefaultDeleter<Container, /* valueTypeIsPair = */ true>
{
  void operator()(typename Container::value_type value) {
    delete value.second;
  }
};

template<typename const_iterator_>
struct Range
{
  typedef const_iterator_ const_iterator;
  typedef typename std::iterator_traits<const_iterator>::value_type value_type;
  Range(const_iterator begin_, const_iterator end_)
    : Begin(begin_), End(end_) {}
  const_iterator begin() const { return Begin; }
  const_iterator end() const { return End; }
  bool empty() const { return std::distance(Begin, End) == 0; }
  Range& advance(cmIML_INT_intptr_t amount)
  {
    std::advance(Begin, amount);
    return *this;
  }

  Range& retreat(cmIML_INT_intptr_t amount)
  {
    std::advance(End, -amount);
    return *this;
  }
private:
  const_iterator Begin;
  const_iterator End;
};

template<typename BiDirIt>
BiDirIt Rotate(BiDirIt first, BiDirIt middle, BiDirIt last)
{
  typename std::iterator_traits<BiDirIt>::difference_type dist =
      std::distance(first, middle);
  std::rotate(first, middle, last);
  std::advance(last, -dist);
  return last;
}

template<typename Iter>
Iter RemoveN(Iter i1, Iter i2, size_t n)
{
  return ContainerAlgorithms::Rotate(i1, i1 + n, i2);
}

template<typename Range>
struct BinarySearcher
{
  typedef typename Range::value_type argument_type;
  BinarySearcher(Range const& r)
    : m_range(r)
  {
  }

  bool operator()(argument_type const& item)
  {
    return std::binary_search(m_range.begin(), m_range.end(), item);
  }
private:
  Range const& m_range;
};

}

template<typename Iter1, typename Iter2>
ContainerAlgorithms::Range<Iter1> cmRange(Iter1 begin, Iter2 end)
{
  return ContainerAlgorithms::Range<Iter1>(begin, end);
}

template<typename Range>
ContainerAlgorithms::Range<typename Range::const_iterator>
cmRange(Range const& range)
{
  return ContainerAlgorithms::Range<typename Range::const_iterator>(
      range.begin(), range.end());
}

template<typename Container>
void cmDeleteAll(Container const& c)
{
  std::for_each(c.begin(), c.end(),
                ContainerAlgorithms::DefaultDeleter<Container>());
}

template<typename Range>
std::string cmJoin(Range const& r, const char* delimiter)
{
  if (r.empty())
    {
    return std::string();
    }
  std::ostringstream os;
  typedef typename Range::value_type ValueType;
  typedef typename Range::const_iterator InputIt;
  InputIt first = r.begin();
  InputIt last = r.end();
  --last;
  std::copy(first, last,
      std::ostream_iterator<ValueType>(os, delimiter));

  os << *last;

  return os.str();
}

template<typename Range>
std::string cmJoin(Range const& r, std::string delimiter)
{
  return cmJoin(r, delimiter.c_str());
};

template<typename Range>
typename Range::const_iterator cmRemoveN(Range& r, size_t n)
{
  return ContainerAlgorithms::RemoveN(r.begin(), r.end(), n);
}

template<typename Range, typename InputRange>
typename Range::const_iterator cmRemoveIndices(Range& r, InputRange const& rem)
{
  typename InputRange::const_iterator remIt = rem.begin();

  typename Range::iterator writer = r.begin() + *remIt;
  ++remIt;
  size_t count = 1;
  for ( ; writer != r.end() && remIt != rem.end(); ++count, ++remIt)
    {
    writer = ContainerAlgorithms::RemoveN(writer, r.begin() + *remIt, count);
    }
  writer = ContainerAlgorithms::RemoveN(writer, r.end(), count);
  return writer;
}

template<typename Range, typename MatchRange>
typename Range::const_iterator cmRemoveMatching(Range &r, MatchRange const& m)
{
  return std::remove_if(r.begin(), r.end(),
                        ContainerAlgorithms::BinarySearcher<MatchRange>(m));
}

#endif
Split cmAlgorithms into a separate header file. 2015-02-10 23:50:16 +03:00			`/*============================================================================`
			`CMake - Cross Platform Makefile Generator`
			`Copyright 2015 Stephen Kelly <steveire@gmail.com>`

			`Distributed under the OSI-approved BSD License (the "License");`
			`see accompanying file Copyright.txt for details.`

			`This software is distributed WITHOUT ANY WARRANTY; without even the`
			`implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.`
			`See the License for more information.`
			`============================================================================*/`
			`#ifndef cmAlgorithms_h`
			`#define cmAlgorithms_h`

			`#include "cmStandardIncludes.h"`

			`inline bool cmHasLiteralPrefixImpl(const std::string &str1,`
			`const char *str2,`
			`size_t N)`
			`{`
			`return strncmp(str1.c_str(), str2, N) == 0;`
			`}`

			`inline bool cmHasLiteralPrefixImpl(const char* str1,`
			`const char *str2,`
			`size_t N)`
			`{`
			`return strncmp(str1, str2, N) == 0;`
			`}`

			`inline bool cmHasLiteralSuffixImpl(const std::string &str1,`
			`const char *str2,`
			`size_t N)`
			`{`
			`size_t len = str1.size();`
			`return len >= N && strcmp(str1.c_str() + len - N, str2) == 0;`
			`}`

			`inline bool cmHasLiteralSuffixImpl(const char* str1,`
			`const char* str2,`
			`size_t N)`
			`{`
			`size_t len = strlen(str1);`
			`return len >= N && strcmp(str1 + len - N, str2) == 0;`
			`}`

			`template<typename T, size_t N>`
			`const T* cmArrayBegin(const T (&a)[N]) { return a; }`
			`template<typename T, size_t N>`
			`const T* cmArrayEnd(const T (&a)[N]) { return a + N; }`
			`template<typename T, size_t N>`
			`size_t cmArraySize(const T (&)[N]) { return N; }`

			`template<typename T, size_t N>`
			`bool cmHasLiteralPrefix(T str1, const char (&str2)[N])`
			`{`
			`return cmHasLiteralPrefixImpl(str1, str2, N - 1);`
			`}`

			`template<typename T, size_t N>`
			`bool cmHasLiteralSuffix(T str1, const char (&str2)[N])`
			`{`
			`return cmHasLiteralSuffixImpl(str1, str2, N - 1);`
			`}`

			`struct cmStrCmp {`
			`cmStrCmp(const char *test) : m_test(test) {}`
			`cmStrCmp(const std::string &test) : m_test(test) {}`

			`bool operator()(const std::string& input) const`
			`{`
			`return m_test == input;`
			`}`

			`bool operator()(const char * input) const`
			`{`
			`return strcmp(input, m_test.c_str()) == 0;`
			`}`

			`private:`
			`const std::string m_test;`
			`};`

			`namespace ContainerAlgorithms {`

			`template<typename T>`
			`struct cmIsPair`
			`{`
			`enum { value = false };`
			`};`

			`template<typename K, typename V>`
			`struct cmIsPair<std::pair<K, V> >`
			`{`
			`enum { value = true };`
			`};`

			`template<typename Container,`
			`bool valueTypeIsPair = cmIsPair<typename Container::value_type>::value>`
			`struct DefaultDeleter`
			`{`
			`void operator()(typename Container::value_type value) {`
			`delete value;`
			`}`
			`};`

			`template<typename Container>`
			`struct DefaultDeleter<Container, /* valueTypeIsPair = */ true>`
			`{`
			`void operator()(typename Container::value_type value) {`
			`delete value.second;`
			`}`
			`};`

cmAlgorithms: Add a Range container and adaptor method. This can make a pair of iterators API compatible with the cmJoin algorithm and other range-based algorithms. Accept different iterator types in the cmRange adaptor so that a const and non-const iterator are accepted. 2015-02-11 00:19:21 +03:00			`template<typename const_iterator_>`
			`struct Range`
			`{`
			`typedef const_iterator_ const_iterator;`
			`typedef typename std::iterator_traits<const_iterator>::value_type value_type;`
			`Range(const_iterator begin_, const_iterator end_)`
			`: Begin(begin_), End(end_) {}`
			`const_iterator begin() const { return Begin; }`
			`const_iterator end() const { return End; }`
			`bool empty() const { return std::distance(Begin, End) == 0; }`
cmAlgorithms: Add a range adaptor and API for adjusting a range. 2015-02-11 00:14:54 +03:00			`Range& advance(cmIML_INT_intptr_t amount)`
			`{`
			`std::advance(Begin, amount);`
			`return *this;`
			`}`

			`Range& retreat(cmIML_INT_intptr_t amount)`
			`{`
			`std::advance(End, -amount);`
			`return *this;`
			`}`
cmAlgorithms: Add a Range container and adaptor method. This can make a pair of iterators API compatible with the cmJoin algorithm and other range-based algorithms. Accept different iterator types in the cmRange adaptor so that a const and non-const iterator are accepted. 2015-02-11 00:19:21 +03:00			`private:`
			`const_iterator Begin;`
			`const_iterator End;`
			`};`

cmAlgorithms: Implement algorithm for removing indexes. Implement ContainerAlgorithms::RemoveN to remove N elements to the end of a container by rotating. The rotate is implemented in terms of the efficient swap algorithm, optimized even more in the standard library implementation when the compiler supports the rvalue-references feature to move elements. Implement cmRemoveN with a Range API for completeness. std::rotate in C++11 is specified to return an iterator, but c++98 specifies it to return void. libstdc++ 5.0 will be the first version to have the correct return type. Implement ContainerAlgorithms::Rotate in terms of std::rotate and return the correct iterator from it. While std::rotate requires forward iterators, this workaround means cmRotate requires bidirectional iterators. As most of CMake uses random access iterators anyway, this should not be a problem. Implement cmRemoveIndices in terms of the RemoveN algorithm, such that each element which is not removed is rotated only once. This can not use the cmRemoveN range-API algorithm because that would require creating a new range, but the range must be taken by reference and so it can't be a temporary. These remove algorithms are not part of the STL and I couldn't find them anywhere else either. 2015-02-12 20:47:10 +03:00			`template<typename BiDirIt>`
			`BiDirIt Rotate(BiDirIt first, BiDirIt middle, BiDirIt last)`
			`{`
			`typename std::iterator_traits<BiDirIt>::difference_type dist =`
			`std::distance(first, middle);`
			`std::rotate(first, middle, last);`
			`std::advance(last, -dist);`
			`return last;`
			`}`

			`template<typename Iter>`
			`Iter RemoveN(Iter i1, Iter i2, size_t n)`
			`{`
			`return ContainerAlgorithms::Rotate(i1, i1 + n, i2);`
			`}`

cmAlgorithms: Add cmRemoveMatching algorithm. Implement it in terms of std::remove_if with a binary search through a matching range. 2015-02-15 20:58:36 +03:00			`template<typename Range>`
			`struct BinarySearcher`
			`{`
			`typedef typename Range::value_type argument_type;`
			`BinarySearcher(Range const& r)`
			`: m_range(r)`
			`{`
			`}`

			`bool operator()(argument_type const& item)`
			`{`
			`return std::binary_search(m_range.begin(), m_range.end(), item);`
			`}`
			`private:`
			`Range const& m_range;`
			`};`

cmAlgorithms: Add a Range container and adaptor method. This can make a pair of iterators API compatible with the cmJoin algorithm and other range-based algorithms. Accept different iterator types in the cmRange adaptor so that a const and non-const iterator are accepted. 2015-02-11 00:19:21 +03:00			`}`

			`template<typename Iter1, typename Iter2>`
			`ContainerAlgorithms::Range<Iter1> cmRange(Iter1 begin, Iter2 end)`
			`{`
			`return ContainerAlgorithms::Range<Iter1>(begin, end);`
Split cmAlgorithms into a separate header file. 2015-02-10 23:50:16 +03:00			`}`

cmAlgorithms: Add a range adaptor and API for adjusting a range. 2015-02-11 00:14:54 +03:00			`template<typename Range>`
			`ContainerAlgorithms::Range<typename Range::const_iterator>`
			`cmRange(Range const& range)`
			`{`
			`return ContainerAlgorithms::Range<typename Range::const_iterator>(`
			`range.begin(), range.end());`
			`}`

Split cmAlgorithms into a separate header file. 2015-02-10 23:50:16 +03:00			`template<typename Container>`
			`void cmDeleteAll(Container const& c)`
			`{`
			`std::for_each(c.begin(), c.end(),`
			`ContainerAlgorithms::DefaultDeleter<Container>());`
			`}`

			`template<typename Range>`
			`std::string cmJoin(Range const& r, const char* delimiter)`
			`{`
			`if (r.empty())`
			`{`
			`return std::string();`
			`}`
			`std::ostringstream os;`
			`typedef typename Range::value_type ValueType;`
			`typedef typename Range::const_iterator InputIt;`
			`InputIt first = r.begin();`
			`InputIt last = r.end();`
			`--last;`
			`std::copy(first, last,`
			`std::ostream_iterator<ValueType>(os, delimiter));`

			`os << *last;`

			`return os.str();`
			`}`

			`template<typename Range>`
			`std::string cmJoin(Range const& r, std::string delimiter)`
			`{`
			`return cmJoin(r, delimiter.c_str());`
			`};`

cmAlgorithms: Implement algorithm for removing indexes. Implement ContainerAlgorithms::RemoveN to remove N elements to the end of a container by rotating. The rotate is implemented in terms of the efficient swap algorithm, optimized even more in the standard library implementation when the compiler supports the rvalue-references feature to move elements. Implement cmRemoveN with a Range API for completeness. std::rotate in C++11 is specified to return an iterator, but c++98 specifies it to return void. libstdc++ 5.0 will be the first version to have the correct return type. Implement ContainerAlgorithms::Rotate in terms of std::rotate and return the correct iterator from it. While std::rotate requires forward iterators, this workaround means cmRotate requires bidirectional iterators. As most of CMake uses random access iterators anyway, this should not be a problem. Implement cmRemoveIndices in terms of the RemoveN algorithm, such that each element which is not removed is rotated only once. This can not use the cmRemoveN range-API algorithm because that would require creating a new range, but the range must be taken by reference and so it can't be a temporary. These remove algorithms are not part of the STL and I couldn't find them anywhere else either. 2015-02-12 20:47:10 +03:00			`template<typename Range>`
			`typename Range::const_iterator cmRemoveN(Range& r, size_t n)`
			`{`
			`return ContainerAlgorithms::RemoveN(r.begin(), r.end(), n);`
			`}`

			`template<typename Range, typename InputRange>`
			`typename Range::const_iterator cmRemoveIndices(Range& r, InputRange const& rem)`
			`{`
			`typename InputRange::const_iterator remIt = rem.begin();`

			`typename Range::iterator writer = r.begin() + *remIt;`
			`++remIt;`
			`size_t count = 1;`
			`for ( ; writer != r.end() && remIt != rem.end(); ++count, ++remIt)`
			`{`
			`writer = ContainerAlgorithms::RemoveN(writer, r.begin() + *remIt, count);`
			`}`
			`writer = ContainerAlgorithms::RemoveN(writer, r.end(), count);`
			`return writer;`
			`}`

cmAlgorithms: Add cmRemoveMatching algorithm. Implement it in terms of std::remove_if with a binary search through a matching range. 2015-02-15 20:58:36 +03:00			`template<typename Range, typename MatchRange>`
			`typename Range::const_iterator cmRemoveMatching(Range &r, MatchRange const& m)`
			`{`
			`return std::remove_if(r.begin(), r.end(),`
			`ContainerAlgorithms::BinarySearcher<MatchRange>(m));`
			`}`

Split cmAlgorithms into a separate header file. 2015-02-10 23:50:16 +03:00			`#endif`