faux-folly/folly/Foreach.h - nest-cam/4320010/faux-folly - Git at Google

 /*
  * Copyright 2015 Facebook, Inc.
  *
  * Licensed under the Apache License, Version 2.0 (the "License");
  * you may not use this file except in compliance with the License.
  * You may obtain a copy of the License at
  *
  *   http://www.apache.org/licenses/LICENSE-2.0
  *
  * Unless required by applicable law or agreed to in writing, software
  * distributed under the License is distributed on an "AS IS" BASIS,
  * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
  * See the License for the specific language governing permissions and
  * limitations under the License.
  */

 #ifndef FOLLY_BASE_FOREACH_H_
 #define FOLLY_BASE_FOREACH_H_

 /*
  * Iterim macros (until we have C++0x range-based for) that simplify
  * writing loops of the form
  *
  * for (Container<data>::iterator i = c.begin(); i != c.end(); ++i) statement
  *
  * Just replace the above with:
  *
  * FOR_EACH (i, c) statement
  *
  * and everything is taken care of.
  *
  * The implementation is a bit convoluted to make sure the container is
  * only evaluated once (however, keep in mind that c.end() is evaluated
  * at every pass through the loop). To ensure the container is not
  * evaluated multiple times, the macro defines one do-nothing if
  * statement to inject the Boolean variable FOR_EACH_state1, and then a
  * for statement that is executed only once, which defines the variable
  * FOR_EACH_state2 holding a rvalue reference to the container being
  * iterated. The workhorse is the last loop, which uses the just defined
  * rvalue reference FOR_EACH_state2.
  *
  * The state variables are nested so they don't interfere; you can use
  * FOR_EACH multiple times in the same scope, either at the same level or
  * nested.
  *
  * In optimized builds g++ eliminates the extra gymnastics entirely and
  * generates code 100% identical to the handwritten loop.
  */

 #include <type_traits>

 /*
  * Shorthand for:
  *   for (auto i = c.begin(); i != c.end(); ++i)
  * except that c is only evaluated once.
  */
 #define FOR_EACH(i, c)                              \
   if (bool FOR_EACH_state1 = false) {} else         \
     for (auto && FOR_EACH_state2 = (c);             \
          !FOR_EACH_state1; FOR_EACH_state1 = true)  \
       for (auto i = FOR_EACH_state2.begin();        \
            i != FOR_EACH_state2.end(); ++i)

 /*
  * Similar to FOR_EACH, but iterates the container backwards by
  * using rbegin() and rend().
  */
 #define FOR_EACH_R(i, c)                                \
   if (bool FOR_EACH_R_state1 = false) {} else           \
     for (auto && FOR_EACH_R_state2 = (c);               \
          !FOR_EACH_R_state1; FOR_EACH_R_state1 = true)  \
       for (auto i = FOR_EACH_R_state2.rbegin();         \
            i != FOR_EACH_R_state2.rend(); ++i)

 /*
  * Similar to FOR_EACH but also allows client to specify a 'count' variable
  * to track the current iteration in the loop (starting at zero).
  * Similar to python's enumerate() function.  For example:
  * string commaSeparatedValues = "VALUES: ";
  * FOR_EACH_ENUMERATE(ii, value, columns) {   // don't want comma at the end!
  *   commaSeparatedValues += (ii == 0) ? *value : string(",") + *value;
  * }
  */
 #define FOR_EACH_ENUMERATE(count, i, c)                                \
   if (bool FOR_EACH_state1 = false) {} else                            \
     for (auto && FOR_EACH_state2 = (c);                                \
          !FOR_EACH_state1; FOR_EACH_state1 = true)                     \
       if (size_t FOR_EACH_privateCount = 0) {} else                    \
         if (const size_t& count = FOR_EACH_privateCount) {} else       \
           for (auto i = FOR_EACH_state2.begin();                       \
                i != FOR_EACH_state2.end(); ++FOR_EACH_privateCount, ++i)

 /**
  * Similar to FOR_EACH, but gives the user the key and value for each entry in
  * the container, instead of just the iterator to the entry. For example:
  *   map<string, string> testMap;
  *   FOR_EACH_KV(key, value, testMap) {
  *      cout << key << " " << value;
  *   }
  */
 #define FOR_EACH_KV(k, v, c)                                    \
   if (unsigned int FOR_EACH_state1 = 0) {} else                 \
     for (auto && FOR_EACH_state2 = (c);                         \
          !FOR_EACH_state1; FOR_EACH_state1 = 1)                 \
       for (auto FOR_EACH_state3 = FOR_EACH_state2.begin();      \
            FOR_EACH_state3 != FOR_EACH_state2.end();            \
            FOR_EACH_state1 == 2                                 \
              ? ((FOR_EACH_state1 = 0), ++FOR_EACH_state3)       \
              : (FOR_EACH_state3 = FOR_EACH_state2.end()))       \
         for (auto &k = FOR_EACH_state3->first;                  \
              !FOR_EACH_state1; ++FOR_EACH_state1)               \
           for (auto &v = FOR_EACH_state3->second;               \
                !FOR_EACH_state1; ++FOR_EACH_state1)

 namespace folly { namespace detail {

 // Boost 1.48 lacks has_less, we emulate a subset of it here.
 template <typename T, typename U>
 class HasLess {
   struct BiggerThanChar { char unused[2]; };
   template <typename C, typename D> static char test(decltype(C() < D())*);
   template <typename, typename> static BiggerThanChar test(...);
 public:
   enum { value = sizeof(test<T, U>(0)) == 1 };
 };

 /**
  * notThereYet helps the FOR_EACH_RANGE macro by opportunistically
  * using "<" instead of "!=" whenever available when checking for loop
  * termination. This makes e.g. examples such as FOR_EACH_RANGE (i,
  * 10, 5) execute zero iterations instead of looping virtually
  * forever. At the same time, some iterator types define "!=" but not
  * "<". The notThereYet function will dispatch differently for those.
  *
  * Below is the correct implementation of notThereYet. It is disabled
  * because of a bug in Boost 1.46: The filesystem::path::iterator
  * defines operator< (via boost::iterator_facade), but that in turn
  * uses distance_to which is undefined for that particular
  * iterator. So HasLess (defined above) identifies
  * boost::filesystem::path as properly comparable with <, but in fact
  * attempting to do so will yield a compile-time error.
  *
  * The else branch (active) contains a conservative
  * implementation.
  */

 #if 0

 template <class T, class U>
 typename std::enable_if<HasLess<T, U>::value, bool>::type
 notThereYet(T& iter, const U& end) {
   return iter < end;
 }

 template <class T, class U>
 typename std::enable_if<!HasLess<T, U>::value, bool>::type
 notThereYet(T& iter, const U& end) {
   return iter != end;
 }

 #else

 template <class T, class U>
 typename std::enable_if<
   (std::is_arithmetic<T>::value && std::is_arithmetic<U>::value) ||
   (std::is_pointer<T>::value && std::is_pointer<U>::value),
   bool>::type
 notThereYet(T& iter, const U& end) {
   return iter < end;
 }

 template <class T, class U>
 typename std::enable_if<
   !(
     (std::is_arithmetic<T>::value && std::is_arithmetic<U>::value) ||
     (std::is_pointer<T>::value && std::is_pointer<U>::value)
   ),
   bool>::type
 notThereYet(T& iter, const U& end) {
   return iter != end;
 }

 #endif


 /**
  * downTo is similar to notThereYet, but in reverse - it helps the
  * FOR_EACH_RANGE_R macro.
  */
 template <class T, class U>
 typename std::enable_if<HasLess<U, T>::value, bool>::type
 downTo(T& iter, const U& begin) {
   return begin < iter--;
 }

 template <class T, class U>
 typename std::enable_if<!HasLess<U, T>::value, bool>::type
 downTo(T& iter, const U& begin) {
   if (iter == begin) return false;
   --iter;
   return true;
 }

 } }

 /*
  * Iteration with given limits. end is assumed to be reachable from
  * begin. end is evaluated every pass through the loop.
  *
  * NOTE: The type of the loop variable should be the common type of "begin"
  *       and "end". e.g. If "begin" is "int" but "end" is "long", we want "i"
  *       to be "long". This is done by getting the type of (true ? begin : end)
  */
 #define FOR_EACH_RANGE(i, begin, end)           \
   for (auto i = (true ? (begin) : (end));       \
        ::folly::detail::notThereYet(i, (end));  \
        ++i)

 /*
  * Iteration with given limits. begin is assumed to be reachable from
  * end by successive decrements. begin is evaluated every pass through
  * the loop.
  *
  * NOTE: The type of the loop variable should be the common type of "begin"
  *       and "end". e.g. If "begin" is "int" but "end" is "long", we want "i"
  *       to be "long". This is done by getting the type of (false ? begin : end)
  */
 #define FOR_EACH_RANGE_R(i, begin, end) \
   for (auto i = (false ? (begin) : (end)); ::folly::detail::downTo(i, (begin));)

 #endif
	/*
	* Copyright 2015 Facebook, Inc.
	*
	* Licensed under the Apache License, Version 2.0 (the "License");
	* you may not use this file except in compliance with the License.
	* You may obtain a copy of the License at
	*
	* http://www.apache.org/licenses/LICENSE-2.0
	*
	* Unless required by applicable law or agreed to in writing, software
	* distributed under the License is distributed on an "AS IS" BASIS,
	* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
	* See the License for the specific language governing permissions and
	* limitations under the License.
	*/

	#ifndef FOLLY_BASE_FOREACH_H_
	#define FOLLY_BASE_FOREACH_H_

	/*
	* Iterim macros (until we have C++0x range-based for) that simplify
	* writing loops of the form
	*
	* for (Container<data>::iterator i = c.begin(); i != c.end(); ++i) statement
	*
	* Just replace the above with:
	*
	* FOR_EACH (i, c) statement
	*
	* and everything is taken care of.
	*
	* The implementation is a bit convoluted to make sure the container is
	* only evaluated once (however, keep in mind that c.end() is evaluated
	* at every pass through the loop). To ensure the container is not
	* evaluated multiple times, the macro defines one do-nothing if
	* statement to inject the Boolean variable FOR_EACH_state1, and then a
	* for statement that is executed only once, which defines the variable
	* FOR_EACH_state2 holding a rvalue reference to the container being
	* iterated. The workhorse is the last loop, which uses the just defined
	* rvalue reference FOR_EACH_state2.
	*
	* The state variables are nested so they don't interfere; you can use
	* FOR_EACH multiple times in the same scope, either at the same level or
	* nested.
	*
	* In optimized builds g++ eliminates the extra gymnastics entirely and
	* generates code 100% identical to the handwritten loop.
	*/

	#include <type_traits>

	/*
	* Shorthand for:
	* for (auto i = c.begin(); i != c.end(); ++i)
	* except that c is only evaluated once.
	*/
	#define FOR_EACH(i, c) \
	if (bool FOR_EACH_state1 = false) {} else \
	for (auto && FOR_EACH_state2 = (c); \
	!FOR_EACH_state1; FOR_EACH_state1 = true) \
	for (auto i = FOR_EACH_state2.begin(); \
	i != FOR_EACH_state2.end(); ++i)

	/*
	* Similar to FOR_EACH, but iterates the container backwards by
	* using rbegin() and rend().
	*/
	#define FOR_EACH_R(i, c) \
	if (bool FOR_EACH_R_state1 = false) {} else \
	for (auto && FOR_EACH_R_state2 = (c); \
	!FOR_EACH_R_state1; FOR_EACH_R_state1 = true) \
	for (auto i = FOR_EACH_R_state2.rbegin(); \
	i != FOR_EACH_R_state2.rend(); ++i)

	/*
	* Similar to FOR_EACH but also allows client to specify a 'count' variable
	* to track the current iteration in the loop (starting at zero).
	* Similar to python's enumerate() function. For example:
	* string commaSeparatedValues = "VALUES: ";
	* FOR_EACH_ENUMERATE(ii, value, columns) { // don't want comma at the end!
	* commaSeparatedValues += (ii == 0) ? value : string(",") + value;
	* }
	*/
	#define FOR_EACH_ENUMERATE(count, i, c) \
	if (bool FOR_EACH_state1 = false) {} else \
	for (auto && FOR_EACH_state2 = (c); \
	!FOR_EACH_state1; FOR_EACH_state1 = true) \
	if (size_t FOR_EACH_privateCount = 0) {} else \
	if (const size_t& count = FOR_EACH_privateCount) {} else \
	for (auto i = FOR_EACH_state2.begin(); \
	i != FOR_EACH_state2.end(); ++FOR_EACH_privateCount, ++i)

	/**
	* Similar to FOR_EACH, but gives the user the key and value for each entry in
	* the container, instead of just the iterator to the entry. For example:
	* map<string, string> testMap;
	* FOR_EACH_KV(key, value, testMap) {
	* cout << key << " " << value;
	* }
	*/
	#define FOR_EACH_KV(k, v, c) \
	if (unsigned int FOR_EACH_state1 = 0) {} else \
	for (auto && FOR_EACH_state2 = (c); \
	!FOR_EACH_state1; FOR_EACH_state1 = 1) \
	for (auto FOR_EACH_state3 = FOR_EACH_state2.begin(); \
	FOR_EACH_state3 != FOR_EACH_state2.end(); \
	FOR_EACH_state1 == 2 \
	? ((FOR_EACH_state1 = 0), ++FOR_EACH_state3) \
	: (FOR_EACH_state3 = FOR_EACH_state2.end())) \
	for (auto &k = FOR_EACH_state3->first; \
	!FOR_EACH_state1; ++FOR_EACH_state1) \
	for (auto &v = FOR_EACH_state3->second; \
	!FOR_EACH_state1; ++FOR_EACH_state1)

	namespace folly { namespace detail {

	// Boost 1.48 lacks has_less, we emulate a subset of it here.
	template <typename T, typename U>
	class HasLess {
	struct BiggerThanChar { char unused[2]; };
	template <typename C, typename D> static char test(decltype(C() < D())*);
	template <typename, typename> static BiggerThanChar test(...);
	public:
	enum { value = sizeof(test<T, U>(0)) == 1 };
	};

	/**
	* notThereYet helps the FOR_EACH_RANGE macro by opportunistically
	* using "<" instead of "!=" whenever available when checking for loop
	* termination. This makes e.g. examples such as FOR_EACH_RANGE (i,
	* 10, 5) execute zero iterations instead of looping virtually
	* forever. At the same time, some iterator types define "!=" but not
	* "<". The notThereYet function will dispatch differently for those.
	*
	* Below is the correct implementation of notThereYet. It is disabled
	* because of a bug in Boost 1.46: The filesystem::path::iterator
	* defines operator< (via boost::iterator_facade), but that in turn
	* uses distance_to which is undefined for that particular
	* iterator. So HasLess (defined above) identifies
	* boost::filesystem::path as properly comparable with <, but in fact
	* attempting to do so will yield a compile-time error.
	*
	* The else branch (active) contains a conservative
	* implementation.
	*/

	#if 0

	template <class T, class U>
	typename std::enable_if<HasLess<T, U>::value, bool>::type
	notThereYet(T& iter, const U& end) {
	return iter < end;
	}

	template <class T, class U>
	typename std::enable_if<!HasLess<T, U>::value, bool>::type
	notThereYet(T& iter, const U& end) {
	return iter != end;
	}

	#else

	template <class T, class U>
	typename std::enable_if<
	(std::is_arithmetic<T>::value && std::is_arithmetic<U>::value) \|\|
	(std::is_pointer<T>::value && std::is_pointer<U>::value),
	bool>::type
	notThereYet(T& iter, const U& end) {
	return iter < end;
	}

	template <class T, class U>
	typename std::enable_if<
	!(
	(std::is_arithmetic<T>::value && std::is_arithmetic<U>::value) \|\|
	(std::is_pointer<T>::value && std::is_pointer<U>::value)
	),
	bool>::type
	notThereYet(T& iter, const U& end) {
	return iter != end;
	}

	#endif


	/**
	* downTo is similar to notThereYet, but in reverse - it helps the
	* FOR_EACH_RANGE_R macro.
	*/
	template <class T, class U>
	typename std::enable_if<HasLess<U, T>::value, bool>::type
	downTo(T& iter, const U& begin) {
	return begin < iter--;
	}

	template <class T, class U>
	typename std::enable_if<!HasLess<U, T>::value, bool>::type
	downTo(T& iter, const U& begin) {
	if (iter == begin) return false;
	--iter;
	return true;
	}

	} }

	/*
	* Iteration with given limits. end is assumed to be reachable from
	* begin. end is evaluated every pass through the loop.
	*
	* NOTE: The type of the loop variable should be the common type of "begin"
	* and "end". e.g. If "begin" is "int" but "end" is "long", we want "i"
	* to be "long". This is done by getting the type of (true ? begin : end)
	*/
	#define FOR_EACH_RANGE(i, begin, end) \
	for (auto i = (true ? (begin) : (end)); \
	::folly::detail::notThereYet(i, (end)); \
	++i)

	/*
	* Iteration with given limits. begin is assumed to be reachable from
	* end by successive decrements. begin is evaluated every pass through
	* the loop.
	*
	* NOTE: The type of the loop variable should be the common type of "begin"
	* and "end". e.g. If "begin" is "int" but "end" is "long", we want "i"
	* to be "long". This is done by getting the type of (false ? begin : end)
	*/
	#define FOR_EACH_RANGE_R(i, begin, end) \
	for (auto i = (false ? (begin) : (end)); ::folly::detail::downTo(i, (begin));)

	#endif