include/flang/Common/interval.h - llvm-project/flang - Git at Google

 //===-- include/flang/Common/interval.h -------------------------*- C++ -*-===//
 //
 // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
 // See https://llvm.org/LICENSE.txt for license information.
 // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
 //
 //===----------------------------------------------------------------------===//

 #ifndef FORTRAN_COMMON_INTERVAL_H_
 #define FORTRAN_COMMON_INTERVAL_H_

 // Defines a generalized template class Interval<A> to represent
 // the half-open interval [x .. x+n).

 #include "idioms.h"
 #include <algorithm>
 #include <cstddef>
 #include <utility>

 namespace Fortran::common {

 template <typename A> class Interval {
 public:
   using type = A;
   constexpr Interval() {}
   constexpr Interval(const A &s, std::size_t n = 1) : start_{s}, size_{n} {}
   constexpr Interval(A &&s, std::size_t n = 1)
       : start_{std::move(s)}, size_{n} {}
   constexpr Interval(const Interval &) = default;
   constexpr Interval(Interval &&) = default;
   constexpr Interval &operator=(const Interval &) = default;
   constexpr Interval &operator=(Interval &&) = default;

   constexpr bool operator<(const Interval &that) const {
     return start_ < that.start_ ||
         (start_ == that.start_ && size_ < that.size_);
   }
   constexpr bool operator<=(const Interval &that) const {
     return start_ < that.start_ ||
         (start_ == that.start_ && size_ <= that.size_);
   }
   constexpr bool operator==(const Interval &that) const {
     return start_ == that.start_ && size_ == that.size_;
   }
   constexpr bool operator!=(const Interval &that) const {
     return !(*this == that);
   }
   constexpr bool operator>=(const Interval &that) const {
     return !(*this < that);
   }
   constexpr bool operator>(const Interval &that) const {
     return !(*this <= that);
   }

   constexpr const A &start() const { return start_; }
   constexpr std::size_t size() const { return size_; }
   constexpr bool empty() const { return size_ == 0; }

   constexpr bool Contains(const A &x) const {
     return start_ <= x && x < start_ + size_;
   }
   constexpr bool Contains(const Interval &that) const {
     return Contains(that.start_) && Contains(that.start_ + (that.size_ - 1));
   }
   constexpr bool IsDisjointWith(const Interval &that) const {
     return that.NextAfter() <= start_ || NextAfter() <= that.start_;
   }
   constexpr bool ImmediatelyPrecedes(const Interval &that) const {
     return NextAfter() == that.start_;
   }
   void Annex(const Interval &that) {
     size_ = (that.start_ + that.size_) - start_;
   }
   bool AnnexIfPredecessor(const Interval &that) {
     if (ImmediatelyPrecedes(that)) {
       size_ += that.size_;
       return true;
     }
     return false;
   }
   void ExtendToCover(const Interval &that) {
     if (size_ == 0) {
       *this = that;
     } else if (that.size_ != 0) {
       const auto end{std::max(NextAfter(), that.NextAfter())};
       start_ = std::min(start_, that.start_);
       size_ = end - start_;
     }
   }

   std::size_t MemberOffset(const A &x) const {
     CHECK(Contains(x));
     return x - start_;
   }
   A OffsetMember(std::size_t n) const {
     CHECK(n <= size_);
     return start_ + n;
   }

   constexpr A Last() const { return start_ + (size_ - 1); }
   constexpr A NextAfter() const { return start_ + size_; }
   constexpr Interval Prefix(std::size_t n) const {
     return {start_, std::min(size_, n)};
   }
   Interval Suffix(std::size_t n) const {
     CHECK(n <= size_);
     return {start_ + n, size_ - n};
   }

   constexpr Interval Intersection(const Interval &that) const {
     if (that.NextAfter() <= start_) {
       return {};
     } else if (that.start_ <= start_) {
       auto skip{start_ - that.start_};
       return {start_, std::min(size_, that.size_ - skip)};
     } else if (NextAfter() <= that.start_) {
       return {};
     } else {
       auto skip{that.start_ - start_};
       return {that.start_, std::min(that.size_, size_ - skip)};
     }
   }

 private:
   A start_;
   std::size_t size_{0};
 };
 } // namespace Fortran::common
 #endif // FORTRAN_COMMON_INTERVAL_H_
	//===-- include/flang/Common/interval.h -------------------------- C++ --===//
	//
	// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
	// See https://llvm.org/LICENSE.txt for license information.
	// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
	//
	//===----------------------------------------------------------------------===//

	#ifndef FORTRAN_COMMON_INTERVAL_H_
	#define FORTRAN_COMMON_INTERVAL_H_

	// Defines a generalized template class Interval<A> to represent
	// the half-open interval [x .. x+n).

	#include "idioms.h"
	#include <algorithm>
	#include <cstddef>
	#include <utility>

	namespace Fortran::common {

	template <typename A> class Interval {
	public:
	using type = A;
	constexpr Interval() {}
	constexpr Interval(const A &s, std::size_t n = 1) : start_{s}, size_{n} {}
	constexpr Interval(A &&s, std::size_t n = 1)
	: start_{std::move(s)}, size_{n} {}
	constexpr Interval(const Interval &) = default;
	constexpr Interval(Interval &&) = default;
	constexpr Interval &operator=(const Interval &) = default;
	constexpr Interval &operator=(Interval &&) = default;

	constexpr bool operator<(const Interval &that) const {
	return start_ < that.start_ \|\|
	(start_ == that.start_ && size_ < that.size_);
	}
	constexpr bool operator<=(const Interval &that) const {
	return start_ < that.start_ \|\|
	(start_ == that.start_ && size_ <= that.size_);
	}
	constexpr bool operator==(const Interval &that) const {
	return start_ == that.start_ && size_ == that.size_;
	}
	constexpr bool operator!=(const Interval &that) const {
	return !(*this == that);
	}
	constexpr bool operator>=(const Interval &that) const {
	return !(*this < that);
	}
	constexpr bool operator>(const Interval &that) const {
	return !(*this <= that);
	}

	constexpr const A &start() const { return start_; }
	constexpr std::size_t size() const { return size_; }
	constexpr bool empty() const { return size_ == 0; }

	constexpr bool Contains(const A &x) const {
	return start_ <= x && x < start_ + size_;
	}
	constexpr bool Contains(const Interval &that) const {
	return Contains(that.start_) && Contains(that.start_ + (that.size_ - 1));
	}
	constexpr bool IsDisjointWith(const Interval &that) const {
	return that.NextAfter() <= start_ \|\| NextAfter() <= that.start_;
	}
	constexpr bool ImmediatelyPrecedes(const Interval &that) const {
	return NextAfter() == that.start_;
	}
	void Annex(const Interval &that) {
	size_ = (that.start_ + that.size_) - start_;
	}
	bool AnnexIfPredecessor(const Interval &that) {
	if (ImmediatelyPrecedes(that)) {
	size_ += that.size_;
	return true;
	}
	return false;
	}
	void ExtendToCover(const Interval &that) {
	if (size_ == 0) {
	*this = that;
	} else if (that.size_ != 0) {
	const auto end{std::max(NextAfter(), that.NextAfter())};
	start_ = std::min(start_, that.start_);
	size_ = end - start_;
	}
	}

	std::size_t MemberOffset(const A &x) const {
	CHECK(Contains(x));
	return x - start_;
	}
	A OffsetMember(std::size_t n) const {
	CHECK(n <= size_);
	return start_ + n;
	}

	constexpr A Last() const { return start_ + (size_ - 1); }
	constexpr A NextAfter() const { return start_ + size_; }
	constexpr Interval Prefix(std::size_t n) const {
	return {start_, std::min(size_, n)};
	}
	Interval Suffix(std::size_t n) const {
	CHECK(n <= size_);
	return {start_ + n, size_ - n};
	}

	constexpr Interval Intersection(const Interval &that) const {
	if (that.NextAfter() <= start_) {
	return {};
	} else if (that.start_ <= start_) {
	auto skip{start_ - that.start_};
	return {start_, std::min(size_, that.size_ - skip)};
	} else if (NextAfter() <= that.start_) {
	return {};
	} else {
	auto skip{that.start_ - start_};
	return {that.start_, std::min(that.size_, size_ - skip)};
	}
	}

	private:
	A start_;
	std::size_t size_{0};
	};
	} // namespace Fortran::common
	#endif // FORTRAN_COMMON_INTERVAL_H_