lib/Evaluate/constant.cpp - llvm-project/flang - Git at Google

 //===-- lib/Evaluate/constant.cpp -----------------------------------------===//
 //
 // 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
 //
 //===----------------------------------------------------------------------===//

 #include "flang/Evaluate/constant.h"
 #include "flang/Evaluate/expression.h"
 #include "flang/Evaluate/shape.h"
 #include "flang/Evaluate/type.h"
 #include <string>

 namespace Fortran::evaluate {

 std::size_t TotalElementCount(const ConstantSubscripts &shape) {
   std::size_t size{1};
   for (auto dim : shape) {
     CHECK(dim >= 0);
     size *= dim;
   }
   return size;
 }

 ConstantBounds::ConstantBounds(const ConstantSubscripts &shape)
     : shape_(shape), lbounds_(shape_.size(), 1) {}

 ConstantBounds::ConstantBounds(ConstantSubscripts &&shape)
     : shape_(std::move(shape)), lbounds_(shape_.size(), 1) {}

 ConstantBounds::~ConstantBounds() = default;

 void ConstantBounds::set_lbounds(ConstantSubscripts &&lb) {
   CHECK(lb.size() == shape_.size());
   lbounds_ = std::move(lb);
 }

 Constant<SubscriptInteger> ConstantBounds::SHAPE() const {
   return AsConstantShape(shape_);
 }

 ConstantSubscript ConstantBounds::SubscriptsToOffset(
     const ConstantSubscripts &index) const {
   CHECK(GetRank(index) == GetRank(shape_));
   ConstantSubscript stride{1}, offset{0};
   int dim{0};
   for (auto j : index) {
     auto lb{lbounds_[dim]};
     auto extent{shape_[dim++]};
     CHECK(j >= lb && j < lb + extent);
     offset += stride * (j - lb);
     stride *= extent;
   }
   return offset;
 }

 bool ConstantBounds::IncrementSubscripts(
     ConstantSubscripts &indices, const std::vector<int> *dimOrder) const {
   int rank{GetRank(shape_)};
   CHECK(GetRank(indices) == rank);
   CHECK(!dimOrder || static_cast<int>(dimOrder->size()) == rank);
   for (int j{0}; j < rank; ++j) {
     ConstantSubscript k{dimOrder ? (*dimOrder)[j] : j};
     auto lb{lbounds_[k]};
     CHECK(indices[k] >= lb);
     if (++indices[k] < lb + shape_[k]) {
       return true;
     } else {
       CHECK(indices[k] == lb + shape_[k]);
       indices[k] = lb;
     }
   }
   return false; // all done
 }

 std::optional<std::vector<int>> ValidateDimensionOrder(
     int rank, const std::vector<int> &order) {
   std::vector<int> dimOrder(rank);
   if (static_cast<int>(order.size()) == rank) {
     std::bitset<common::maxRank> seenDimensions;
     for (int j{0}; j < rank; ++j) {
       int dim{order[j]};
       if (dim < 1 || dim > rank || seenDimensions.test(dim - 1)) {
         return std::nullopt;
       }
       dimOrder[dim - 1] = j;
       seenDimensions.set(dim - 1);
     }
     return dimOrder;
   } else {
     return std::nullopt;
   }
 }

 bool HasNegativeExtent(const ConstantSubscripts &shape) {
   for (ConstantSubscript extent : shape) {
     if (extent < 0) {
       return true;
     }
   }
   return false;
 }

 template <typename RESULT, typename ELEMENT>
 ConstantBase<RESULT, ELEMENT>::ConstantBase(
     std::vector<Element> &&x, ConstantSubscripts &&sh, Result res)
     : ConstantBounds(std::move(sh)), result_{res}, values_(std::move(x)) {
   CHECK(size() == TotalElementCount(shape()));
 }

 template <typename RESULT, typename ELEMENT>
 ConstantBase<RESULT, ELEMENT>::~ConstantBase() {}

 template <typename RESULT, typename ELEMENT>
 bool ConstantBase<RESULT, ELEMENT>::operator==(const ConstantBase &that) const {
   return shape() == that.shape() && values_ == that.values_;
 }

 template <typename RESULT, typename ELEMENT>
 auto ConstantBase<RESULT, ELEMENT>::Reshape(
     const ConstantSubscripts &dims) const -> std::vector<Element> {
   std::size_t n{TotalElementCount(dims)};
   CHECK(!empty() || n == 0);
   std::vector<Element> elements;
   auto iter{values().cbegin()};
   while (n-- > 0) {
     elements.push_back(*iter);
     if (++iter == values().cend()) {
       iter = values().cbegin();
     }
   }
   return elements;
 }

 template <typename RESULT, typename ELEMENT>
 std::size_t ConstantBase<RESULT, ELEMENT>::CopyFrom(
     const ConstantBase<RESULT, ELEMENT> &source, std::size_t count,
     ConstantSubscripts &resultSubscripts, const std::vector<int> *dimOrder) {
   std::size_t copied{0};
   ConstantSubscripts sourceSubscripts{source.lbounds()};
   while (copied < count) {
     values_.at(SubscriptsToOffset(resultSubscripts)) =
         source.values_.at(source.SubscriptsToOffset(sourceSubscripts));
     copied++;
     source.IncrementSubscripts(sourceSubscripts);
     IncrementSubscripts(resultSubscripts, dimOrder);
   }
   return copied;
 }

 template <typename T>
 auto Constant<T>::At(const ConstantSubscripts &index) const -> Element {
   return Base::values_.at(Base::SubscriptsToOffset(index));
 }

 template <typename T>
 auto Constant<T>::Reshape(ConstantSubscripts &&dims) const -> Constant {
   return {Base::Reshape(dims), std::move(dims)};
 }

 template <typename T>
 std::size_t Constant<T>::CopyFrom(const Constant<T> &source, std::size_t count,
     ConstantSubscripts &resultSubscripts, const std::vector<int> *dimOrder) {
   return Base::CopyFrom(source, count, resultSubscripts, dimOrder);
 }

 // Constant<Type<TypeCategory::Character, KIND> specializations
 template <int KIND>
 Constant<Type<TypeCategory::Character, KIND>>::Constant(
     const Scalar<Result> &str)
     : values_{str}, length_{static_cast<ConstantSubscript>(values_.size())} {}

 template <int KIND>
 Constant<Type<TypeCategory::Character, KIND>>::Constant(Scalar<Result> &&str)
     : values_{std::move(str)}, length_{static_cast<ConstantSubscript>(
                                    values_.size())} {}

 template <int KIND>
 Constant<Type<TypeCategory::Character, KIND>>::Constant(ConstantSubscript len,
     std::vector<Scalar<Result>> &&strings, ConstantSubscripts &&sh)
     : ConstantBounds(std::move(sh)), length_{len} {
   CHECK(strings.size() == TotalElementCount(shape()));
   values_.assign(strings.size() * length_,
       static_cast<typename Scalar<Result>::value_type>(' '));
   ConstantSubscript at{0};
   for (const auto &str : strings) {
     auto strLen{static_cast<ConstantSubscript>(str.size())};
     if (strLen > length_) {
       values_.replace(at, length_, str.substr(0, length_));
     } else {
       values_.replace(at, strLen, str);
     }
     at += length_;
   }
   CHECK(at == static_cast<ConstantSubscript>(values_.size()));
 }

 template <int KIND>
 Constant<Type<TypeCategory::Character, KIND>>::~Constant() {}

 template <int KIND>
 bool Constant<Type<TypeCategory::Character, KIND>>::empty() const {
   return size() == 0;
 }

 template <int KIND>
 std::size_t Constant<Type<TypeCategory::Character, KIND>>::size() const {
   if (length_ == 0) {
     return TotalElementCount(shape());
   } else {
     return static_cast<ConstantSubscript>(values_.size()) / length_;
   }
 }

 template <int KIND>
 auto Constant<Type<TypeCategory::Character, KIND>>::At(
     const ConstantSubscripts &index) const -> Scalar<Result> {
   auto offset{SubscriptsToOffset(index)};
   return values_.substr(offset * length_, length_);
 }

 template <int KIND>
 auto Constant<Type<TypeCategory::Character, KIND>>::Reshape(
     ConstantSubscripts &&dims) const -> Constant<Result> {
   std::size_t n{TotalElementCount(dims)};
   CHECK(!empty() || n == 0);
   std::vector<Element> elements;
   ConstantSubscript at{0},
       limit{static_cast<ConstantSubscript>(values_.size())};
   while (n-- > 0) {
     elements.push_back(values_.substr(at, length_));
     at += length_;
     if (at == limit) { // subtle: at > limit somehow? substr() will catch it
       at = 0;
     }
   }
   return {length_, std::move(elements), std::move(dims)};
 }

 template <int KIND>
 std::size_t Constant<Type<TypeCategory::Character, KIND>>::CopyFrom(
     const Constant<Type<TypeCategory::Character, KIND>> &source,
     std::size_t count, ConstantSubscripts &resultSubscripts,
     const std::vector<int> *dimOrder) {
   CHECK(length_ == source.length_);
   if (length_ == 0) {
     // It's possible that the array of strings consists of all empty strings.
     // If so, constant folding will result in a string that's completely empty
     // and the length_ will be zero, and there's nothing to do.
     return count;
   } else {
     std::size_t copied{0};
     std::size_t elementBytes{length_ * sizeof(decltype(values_[0]))};
     ConstantSubscripts sourceSubscripts{source.lbounds()};
     while (copied < count) {
       auto *dest{&values_.at(SubscriptsToOffset(resultSubscripts) * length_)};
       const auto *src{&source.values_.at(
           source.SubscriptsToOffset(sourceSubscripts) * length_)};
       std::memcpy(dest, src, elementBytes);
       copied++;
       source.IncrementSubscripts(sourceSubscripts);
       IncrementSubscripts(resultSubscripts, dimOrder);
     }
     return copied;
   }
 }

 // Constant<SomeDerived> specialization
 Constant<SomeDerived>::Constant(const StructureConstructor &x)
     : Base{x.values(), Result{x.derivedTypeSpec()}} {}

 Constant<SomeDerived>::Constant(StructureConstructor &&x)
     : Base{std::move(x.values()), Result{x.derivedTypeSpec()}} {}

 Constant<SomeDerived>::Constant(const semantics::DerivedTypeSpec &spec,
     std::vector<StructureConstructorValues> &&x, ConstantSubscripts &&s)
     : Base{std::move(x), std::move(s), Result{spec}} {}

 static std::vector<StructureConstructorValues> AcquireValues(
     std::vector<StructureConstructor> &&x) {
   std::vector<StructureConstructorValues> result;
   for (auto &&structure : std::move(x)) {
     result.emplace_back(std::move(structure.values()));
   }
   return result;
 }

 Constant<SomeDerived>::Constant(const semantics::DerivedTypeSpec &spec,
     std::vector<StructureConstructor> &&x, ConstantSubscripts &&shape)
     : Base{AcquireValues(std::move(x)), std::move(shape), Result{spec}} {}

 std::optional<StructureConstructor>
 Constant<SomeDerived>::GetScalarValue() const {
   if (Rank() == 0) {
     return StructureConstructor{result().derivedTypeSpec(), values_.at(0)};
   } else {
     return std::nullopt;
   }
 }

 StructureConstructor Constant<SomeDerived>::At(
     const ConstantSubscripts &index) const {
   return {result().derivedTypeSpec(), values_.at(SubscriptsToOffset(index))};
 }

 auto Constant<SomeDerived>::Reshape(ConstantSubscripts &&dims) const
     -> Constant {
   return {result().derivedTypeSpec(), Base::Reshape(dims), std::move(dims)};
 }

 std::size_t Constant<SomeDerived>::CopyFrom(const Constant<SomeDerived> &source,
     std::size_t count, ConstantSubscripts &resultSubscripts,
     const std::vector<int> *dimOrder) {
   return Base::CopyFrom(source, count, resultSubscripts, dimOrder);
 }

 bool ComponentCompare::operator()(SymbolRef x, SymbolRef y) const {
   return semantics::SymbolSourcePositionCompare{}(x, y);
 }

 INSTANTIATE_CONSTANT_TEMPLATES
 } // namespace Fortran::evaluate
	//===-- lib/Evaluate/constant.cpp -----------------------------------------===//
	//
	// 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
	//
	//===----------------------------------------------------------------------===//

	#include "flang/Evaluate/constant.h"
	#include "flang/Evaluate/expression.h"
	#include "flang/Evaluate/shape.h"
	#include "flang/Evaluate/type.h"
	#include <string>

	namespace Fortran::evaluate {

	std::size_t TotalElementCount(const ConstantSubscripts &shape) {
	std::size_t size{1};
	for (auto dim : shape) {
	CHECK(dim >= 0);
	size *= dim;
	}
	return size;
	}

	ConstantBounds::ConstantBounds(const ConstantSubscripts &shape)
	: shape_(shape), lbounds_(shape_.size(), 1) {}

	ConstantBounds::ConstantBounds(ConstantSubscripts &&shape)
	: shape_(std::move(shape)), lbounds_(shape_.size(), 1) {}

	ConstantBounds::~ConstantBounds() = default;

	void ConstantBounds::set_lbounds(ConstantSubscripts &&lb) {
	CHECK(lb.size() == shape_.size());
	lbounds_ = std::move(lb);
	}

	Constant<SubscriptInteger> ConstantBounds::SHAPE() const {
	return AsConstantShape(shape_);
	}

	ConstantSubscript ConstantBounds::SubscriptsToOffset(
	const ConstantSubscripts &index) const {
	CHECK(GetRank(index) == GetRank(shape_));
	ConstantSubscript stride{1}, offset{0};
	int dim{0};
	for (auto j : index) {
	auto lb{lbounds_[dim]};
	auto extent{shape_[dim++]};
	CHECK(j >= lb && j < lb + extent);
	offset += stride * (j - lb);
	stride *= extent;
	}
	return offset;
	}

	bool ConstantBounds::IncrementSubscripts(
	ConstantSubscripts &indices, const std::vector<int> *dimOrder) const {
	int rank{GetRank(shape_)};
	CHECK(GetRank(indices) == rank);
	CHECK(!dimOrder \|\| static_cast<int>(dimOrder->size()) == rank);
	for (int j{0}; j < rank; ++j) {
	ConstantSubscript k{dimOrder ? (*dimOrder)[j] : j};
	auto lb{lbounds_[k]};
	CHECK(indices[k] >= lb);
	if (++indices[k] < lb + shape_[k]) {
	return true;
	} else {
	CHECK(indices[k] == lb + shape_[k]);
	indices[k] = lb;
	}
	}
	return false; // all done
	}

	std::optional<std::vector<int>> ValidateDimensionOrder(
	int rank, const std::vector<int> &order) {
	std::vector<int> dimOrder(rank);
	if (static_cast<int>(order.size()) == rank) {
	std::bitset<common::maxRank> seenDimensions;
	for (int j{0}; j < rank; ++j) {
	int dim{order[j]};
	if (dim < 1 \|\| dim > rank \|\| seenDimensions.test(dim - 1)) {
	return std::nullopt;
	}
	dimOrder[dim - 1] = j;
	seenDimensions.set(dim - 1);
	}
	return dimOrder;
	} else {
	return std::nullopt;
	}
	}

	bool HasNegativeExtent(const ConstantSubscripts &shape) {
	for (ConstantSubscript extent : shape) {
	if (extent < 0) {
	return true;
	}
	}
	return false;
	}

	template <typename RESULT, typename ELEMENT>
	ConstantBase<RESULT, ELEMENT>::ConstantBase(
	std::vector<Element> &&x, ConstantSubscripts &&sh, Result res)
	: ConstantBounds(std::move(sh)), result_{res}, values_(std::move(x)) {
	CHECK(size() == TotalElementCount(shape()));
	}

	template <typename RESULT, typename ELEMENT>
	ConstantBase<RESULT, ELEMENT>::~ConstantBase() {}

	template <typename RESULT, typename ELEMENT>
	bool ConstantBase<RESULT, ELEMENT>::operator==(const ConstantBase &that) const {
	return shape() == that.shape() && values_ == that.values_;
	}

	template <typename RESULT, typename ELEMENT>
	auto ConstantBase<RESULT, ELEMENT>::Reshape(
	const ConstantSubscripts &dims) const -> std::vector<Element> {
	std::size_t n{TotalElementCount(dims)};
	CHECK(!empty() \|\| n == 0);
	std::vector<Element> elements;
	auto iter{values().cbegin()};
	while (n-- > 0) {
	elements.push_back(*iter);
	if (++iter == values().cend()) {
	iter = values().cbegin();
	}
	}
	return elements;
	}

	template <typename RESULT, typename ELEMENT>
	std::size_t ConstantBase<RESULT, ELEMENT>::CopyFrom(
	const ConstantBase<RESULT, ELEMENT> &source, std::size_t count,
	ConstantSubscripts &resultSubscripts, const std::vector<int> *dimOrder) {
	std::size_t copied{0};
	ConstantSubscripts sourceSubscripts{source.lbounds()};
	while (copied < count) {
	values_.at(SubscriptsToOffset(resultSubscripts)) =
	source.values_.at(source.SubscriptsToOffset(sourceSubscripts));
	copied++;
	source.IncrementSubscripts(sourceSubscripts);
	IncrementSubscripts(resultSubscripts, dimOrder);
	}
	return copied;
	}

	template <typename T>
	auto Constant<T>::At(const ConstantSubscripts &index) const -> Element {
	return Base::values_.at(Base::SubscriptsToOffset(index));
	}

	template <typename T>
	auto Constant<T>::Reshape(ConstantSubscripts &&dims) const -> Constant {
	return {Base::Reshape(dims), std::move(dims)};
	}

	template <typename T>
	std::size_t Constant<T>::CopyFrom(const Constant<T> &source, std::size_t count,
	ConstantSubscripts &resultSubscripts, const std::vector<int> *dimOrder) {
	return Base::CopyFrom(source, count, resultSubscripts, dimOrder);
	}

	// Constant<Type<TypeCategory::Character, KIND> specializations
	template <int KIND>
	Constant<Type<TypeCategory::Character, KIND>>::Constant(
	const Scalar<Result> &str)
	: values_{str}, length_{static_cast<ConstantSubscript>(values_.size())} {}

	template <int KIND>
	Constant<Type<TypeCategory::Character, KIND>>::Constant(Scalar<Result> &&str)
	: values_{std::move(str)}, length_{static_cast<ConstantSubscript>(
	values_.size())} {}

	template <int KIND>
	Constant<Type<TypeCategory::Character, KIND>>::Constant(ConstantSubscript len,
	std::vector<Scalar<Result>> &&strings, ConstantSubscripts &&sh)
	: ConstantBounds(std::move(sh)), length_{len} {
	CHECK(strings.size() == TotalElementCount(shape()));
	values_.assign(strings.size() * length_,
	static_cast<typename Scalar<Result>::value_type>(' '));
	ConstantSubscript at{0};
	for (const auto &str : strings) {
	auto strLen{static_cast<ConstantSubscript>(str.size())};
	if (strLen > length_) {
	values_.replace(at, length_, str.substr(0, length_));
	} else {
	values_.replace(at, strLen, str);
	}
	at += length_;
	}
	CHECK(at == static_cast<ConstantSubscript>(values_.size()));
	}

	template <int KIND>
	Constant<Type<TypeCategory::Character, KIND>>::~Constant() {}

	template <int KIND>
	bool Constant<Type<TypeCategory::Character, KIND>>::empty() const {
	return size() == 0;
	}

	template <int KIND>
	std::size_t Constant<Type<TypeCategory::Character, KIND>>::size() const {
	if (length_ == 0) {
	return TotalElementCount(shape());
	} else {
	return static_cast<ConstantSubscript>(values_.size()) / length_;
	}
	}

	template <int KIND>
	auto Constant<Type<TypeCategory::Character, KIND>>::At(
	const ConstantSubscripts &index) const -> Scalar<Result> {
	auto offset{SubscriptsToOffset(index)};
	return values_.substr(offset * length_, length_);
	}

	template <int KIND>
	auto Constant<Type<TypeCategory::Character, KIND>>::Reshape(
	ConstantSubscripts &&dims) const -> Constant<Result> {
	std::size_t n{TotalElementCount(dims)};
	CHECK(!empty() \|\| n == 0);
	std::vector<Element> elements;
	ConstantSubscript at{0},
	limit{static_cast<ConstantSubscript>(values_.size())};
	while (n-- > 0) {
	elements.push_back(values_.substr(at, length_));
	at += length_;
	if (at == limit) { // subtle: at > limit somehow? substr() will catch it
	at = 0;
	}
	}
	return {length_, std::move(elements), std::move(dims)};
	}

	template <int KIND>
	std::size_t Constant<Type<TypeCategory::Character, KIND>>::CopyFrom(
	const Constant<Type<TypeCategory::Character, KIND>> &source,
	std::size_t count, ConstantSubscripts &resultSubscripts,
	const std::vector<int> *dimOrder) {
	CHECK(length_ == source.length_);
	if (length_ == 0) {
	// It's possible that the array of strings consists of all empty strings.
	// If so, constant folding will result in a string that's completely empty
	// and the length_ will be zero, and there's nothing to do.
	return count;
	} else {
	std::size_t copied{0};
	std::size_t elementBytes{length_ * sizeof(decltype(values_[0]))};
	ConstantSubscripts sourceSubscripts{source.lbounds()};
	while (copied < count) {
	auto dest{&values_.at(SubscriptsToOffset(resultSubscripts) length_)};
	const auto *src{&source.values_.at(
	source.SubscriptsToOffset(sourceSubscripts) * length_)};
	std::memcpy(dest, src, elementBytes);
	copied++;
	source.IncrementSubscripts(sourceSubscripts);
	IncrementSubscripts(resultSubscripts, dimOrder);
	}
	return copied;
	}
	}

	// Constant<SomeDerived> specialization
	Constant<SomeDerived>::Constant(const StructureConstructor &x)
	: Base{x.values(), Result{x.derivedTypeSpec()}} {}

	Constant<SomeDerived>::Constant(StructureConstructor &&x)
	: Base{std::move(x.values()), Result{x.derivedTypeSpec()}} {}

	Constant<SomeDerived>::Constant(const semantics::DerivedTypeSpec &spec,
	std::vector<StructureConstructorValues> &&x, ConstantSubscripts &&s)
	: Base{std::move(x), std::move(s), Result{spec}} {}

	static std::vector<StructureConstructorValues> AcquireValues(
	std::vector<StructureConstructor> &&x) {
	std::vector<StructureConstructorValues> result;
	for (auto &&structure : std::move(x)) {
	result.emplace_back(std::move(structure.values()));
	}
	return result;
	}

	Constant<SomeDerived>::Constant(const semantics::DerivedTypeSpec &spec,
	std::vector<StructureConstructor> &&x, ConstantSubscripts &&shape)
	: Base{AcquireValues(std::move(x)), std::move(shape), Result{spec}} {}

	std::optional<StructureConstructor>
	Constant<SomeDerived>::GetScalarValue() const {
	if (Rank() == 0) {
	return StructureConstructor{result().derivedTypeSpec(), values_.at(0)};
	} else {
	return std::nullopt;
	}
	}

	StructureConstructor Constant<SomeDerived>::At(
	const ConstantSubscripts &index) const {
	return {result().derivedTypeSpec(), values_.at(SubscriptsToOffset(index))};
	}

	auto Constant<SomeDerived>::Reshape(ConstantSubscripts &&dims) const
	-> Constant {
	return {result().derivedTypeSpec(), Base::Reshape(dims), std::move(dims)};
	}

	std::size_t Constant<SomeDerived>::CopyFrom(const Constant<SomeDerived> &source,
	std::size_t count, ConstantSubscripts &resultSubscripts,
	const std::vector<int> *dimOrder) {
	return Base::CopyFrom(source, count, resultSubscripts, dimOrder);
	}

	bool ComponentCompare::operator()(SymbolRef x, SymbolRef y) const {
	return semantics::SymbolSourcePositionCompare{}(x, y);
	}

	INSTANTIATE_CONSTANT_TEMPLATES
	} // namespace Fortran::evaluate