lib/Semantics/compute-offsets.cpp - llvm-project/flang - Git at Google

 //===-- lib/Semantics/compute-offsets.cpp -----------------------*- 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
 //
 //===----------------------------------------------------------------------===//

 #include "compute-offsets.h"
 #include "flang/Evaluate/fold-designator.h"
 #include "flang/Evaluate/fold.h"
 #include "flang/Evaluate/shape.h"
 #include "flang/Evaluate/type.h"
 #include "flang/Runtime/descriptor.h"
 #include "flang/Semantics/scope.h"
 #include "flang/Semantics/semantics.h"
 #include "flang/Semantics/symbol.h"
 #include "flang/Semantics/tools.h"
 #include "flang/Semantics/type.h"
 #include <algorithm>
 #include <vector>

 namespace Fortran::semantics {

 class ComputeOffsetsHelper {
 public:
   ComputeOffsetsHelper(SemanticsContext &context) : context_{context} {}
   void Compute(Scope &);

 private:
   struct SizeAndAlignment {
     SizeAndAlignment() {}
     SizeAndAlignment(std::size_t bytes) : size{bytes}, alignment{bytes} {}
     SizeAndAlignment(std::size_t bytes, std::size_t align)
         : size{bytes}, alignment{align} {}
     std::size_t size{0};
     std::size_t alignment{0};
   };
   struct SymbolAndOffset {
     SymbolAndOffset(Symbol &s, std::size_t off, const EquivalenceObject &obj)
         : symbol{s}, offset{off}, object{&obj} {}
     SymbolAndOffset(const SymbolAndOffset &) = default;
     MutableSymbolRef symbol;
     std::size_t offset;
     const EquivalenceObject *object;
   };

   void DoCommonBlock(Symbol &);
   void DoEquivalenceBlockBase(Symbol &, SizeAndAlignment &);
   void DoEquivalenceSet(const EquivalenceSet &);
   SymbolAndOffset Resolve(const SymbolAndOffset &);
   std::size_t ComputeOffset(const EquivalenceObject &);
   // Returns amount of padding that was needed for alignment
   std::size_t DoSymbol(Symbol &);
   SizeAndAlignment GetSizeAndAlignment(const Symbol &, bool entire);
   std::size_t Align(std::size_t, std::size_t);

   SemanticsContext &context_;
   std::size_t offset_{0};
   std::size_t alignment_{1};
   // symbol -> symbol+offset that determines its location, from EQUIVALENCE
   std::map<MutableSymbolRef, SymbolAndOffset, SymbolAddressCompare> dependents_;
   // base symbol -> SizeAndAlignment for each distinct EQUIVALENCE block
   std::map<MutableSymbolRef, SizeAndAlignment, SymbolAddressCompare>
       equivalenceBlock_;
 };

 void ComputeOffsetsHelper::Compute(Scope &scope) {
   for (Scope &child : scope.children()) {
     ComputeOffsets(context_, child);
   }
   if (scope.symbol() && scope.IsDerivedTypeWithKindParameter()) {
     return; // only process instantiations of kind parameterized derived types
   }
   if (scope.alignment().has_value()) {
     return; // prevent infinite recursion in error cases
   }
   scope.SetAlignment(0);
   // Build dependents_ from equivalences: symbol -> symbol+offset
   for (const EquivalenceSet &set : scope.equivalenceSets()) {
     DoEquivalenceSet(set);
   }
   // Compute a base symbol and overall block size for each
   // disjoint EQUIVALENCE storage sequence.
   for (auto &[symbol, dep] : dependents_) {
     dep = Resolve(dep);
     CHECK(symbol->size() == 0);
     auto symInfo{GetSizeAndAlignment(*symbol, true)};
     symbol->set_size(symInfo.size);
     Symbol &base{*dep.symbol};
     auto iter{equivalenceBlock_.find(base)};
     std::size_t minBlockSize{dep.offset + symInfo.size};
     if (iter == equivalenceBlock_.end()) {
       equivalenceBlock_.emplace(
           base, SizeAndAlignment{minBlockSize, symInfo.alignment});
     } else {
       SizeAndAlignment &blockInfo{iter->second};
       blockInfo.size = std::max(blockInfo.size, minBlockSize);
       blockInfo.alignment = std::max(blockInfo.alignment, symInfo.alignment);
     }
   }
   // Assign offsets for non-COMMON EQUIVALENCE blocks
   for (auto &[symbol, blockInfo] : equivalenceBlock_) {
     if (!FindCommonBlockContaining(*symbol)) {
       DoSymbol(*symbol);
       DoEquivalenceBlockBase(*symbol, blockInfo);
       offset_ = std::max(offset_, symbol->offset() + blockInfo.size);
     }
   }
   // Process remaining non-COMMON symbols; this is all of them if there
   // was no use of EQUIVALENCE in the scope.
   for (auto &symbol : scope.GetSymbols()) {
     if (!FindCommonBlockContaining(*symbol) &&
         dependents_.find(symbol) == dependents_.end() &&
         equivalenceBlock_.find(symbol) == equivalenceBlock_.end()) {
       DoSymbol(*symbol);
     }
   }
   // Ensure that the size is a multiple of the alignment
   offset_ = Align(offset_, alignment_);
   scope.set_size(offset_);
   scope.SetAlignment(alignment_);
   // Assign offsets in COMMON blocks, unless this scope is a BLOCK construct,
   // where COMMON blocks are illegal (C1107 and C1108).
   if (scope.kind() != Scope::Kind::BlockConstruct) {
     for (auto &pair : scope.commonBlocks()) {
       DoCommonBlock(*pair.second);
     }
   }
   for (auto &[symbol, dep] : dependents_) {
     symbol->set_offset(dep.symbol->offset() + dep.offset);
     if (const auto *block{FindCommonBlockContaining(*dep.symbol)}) {
       symbol->get<ObjectEntityDetails>().set_commonBlock(*block);
     }
   }
 }

 auto ComputeOffsetsHelper::Resolve(const SymbolAndOffset &dep)
     -> SymbolAndOffset {
   auto it{dependents_.find(*dep.symbol)};
   if (it == dependents_.end()) {
     return dep;
   } else {
     SymbolAndOffset result{Resolve(it->second)};
     result.offset += dep.offset;
     result.object = dep.object;
     return result;
   }
 }

 void ComputeOffsetsHelper::DoCommonBlock(Symbol &commonBlock) {
   auto &details{commonBlock.get<CommonBlockDetails>()};
   offset_ = 0;
   alignment_ = 0;
   std::size_t minSize{0};
   std::size_t minAlignment{0};
   UnorderedSymbolSet previous;
   for (auto object : details.objects()) {
     Symbol &symbol{*object};
     auto errorSite{
         commonBlock.name().empty() ? symbol.name() : commonBlock.name()};
     if (std::size_t padding{DoSymbol(symbol.GetUltimate())}) {
       if (context_.ShouldWarn(common::UsageWarning::CommonBlockPadding)) {
         context_.Say(errorSite,
             "COMMON block /%s/ requires %zd bytes of padding before '%s' for alignment"_port_en_US,
             commonBlock.name(), padding, symbol.name());
       }
     }
     previous.emplace(symbol);
     auto eqIter{equivalenceBlock_.end()};
     auto iter{dependents_.find(symbol)};
     if (iter == dependents_.end()) {
       eqIter = equivalenceBlock_.find(symbol);
       if (eqIter != equivalenceBlock_.end()) {
         DoEquivalenceBlockBase(symbol, eqIter->second);
       }
     } else {
       SymbolAndOffset &dep{iter->second};
       Symbol &base{*dep.symbol};
       if (const auto *baseBlock{FindCommonBlockContaining(base)}) {
         if (baseBlock == &commonBlock) {
           if (previous.find(SymbolRef{base}) == previous.end() ||
               base.offset() != symbol.offset() - dep.offset) {
             context_.Say(errorSite,
                 "'%s' is storage associated with '%s' by EQUIVALENCE elsewhere in COMMON block /%s/"_err_en_US,
                 symbol.name(), base.name(), commonBlock.name());
           }
         } else { // F'2023 8.10.3 p1
           context_.Say(errorSite,
               "'%s' in COMMON block /%s/ must not be storage associated with '%s' in COMMON block /%s/ by EQUIVALENCE"_err_en_US,
               symbol.name(), commonBlock.name(), base.name(),
               baseBlock->name());
         }
       } else if (dep.offset > symbol.offset()) { // 8.10.3(3)
         context_.Say(errorSite,
             "'%s' cannot backward-extend COMMON block /%s/ via EQUIVALENCE with '%s'"_err_en_US,
             symbol.name(), commonBlock.name(), base.name());
       } else {
         eqIter = equivalenceBlock_.find(base);
         base.get<ObjectEntityDetails>().set_commonBlock(commonBlock);
         base.set_offset(symbol.offset() - dep.offset);
         previous.emplace(base);
       }
     }
     // Get full extent of any EQUIVALENCE block into size of COMMON ( see
     // 8.10.2.2 point 1 (2))
     if (eqIter != equivalenceBlock_.end()) {
       SizeAndAlignment &blockInfo{eqIter->second};
       minSize = std::max(
           minSize, std::max(offset_, eqIter->first->offset() + blockInfo.size));
       minAlignment = std::max(minAlignment, blockInfo.alignment);
     }
   }
   commonBlock.set_size(std::max(minSize, offset_));
   details.set_alignment(std::max(minAlignment, alignment_));
   context_.MapCommonBlockAndCheckConflicts(commonBlock);
 }

 void ComputeOffsetsHelper::DoEquivalenceBlockBase(
     Symbol &symbol, SizeAndAlignment &blockInfo) {
   if (symbol.size() > blockInfo.size) {
     blockInfo.size = symbol.size();
   }
 }

 void ComputeOffsetsHelper::DoEquivalenceSet(const EquivalenceSet &set) {
   std::vector<SymbolAndOffset> symbolOffsets;
   std::optional<std::size_t> representative;
   for (const EquivalenceObject &object : set) {
     std::size_t offset{ComputeOffset(object)};
     SymbolAndOffset resolved{
         Resolve(SymbolAndOffset{object.symbol, offset, object})};
     symbolOffsets.push_back(resolved);
     if (!representative ||
         resolved.offset >= symbolOffsets[*representative].offset) {
       // The equivalenced object with the largest offset from its resolved
       // symbol will be the representative of this set, since the offsets
       // of the other objects will be positive relative to it.
       representative = symbolOffsets.size() - 1;
     }
   }
   CHECK(representative);
   const SymbolAndOffset &base{symbolOffsets[*representative]};
   for (const auto &[symbol, offset, object] : symbolOffsets) {
     if (symbol == base.symbol) {
       if (offset != base.offset) {
         auto x{evaluate::OffsetToDesignator(
             context_.foldingContext(), *symbol, base.offset, 1)};
         auto y{evaluate::OffsetToDesignator(
             context_.foldingContext(), *symbol, offset, 1)};
         if (x && y) {
           context_
               .Say(base.object->source,
                   "'%s' and '%s' cannot have the same first storage unit"_err_en_US,
                   x->AsFortran(), y->AsFortran())
               .Attach(object->source, "Incompatible reference to '%s'"_en_US,
                   y->AsFortran());
         } else { // error recovery
           context_
               .Say(base.object->source,
                   "'%s' (offset %zd bytes and %zd bytes) cannot have the same first storage unit"_err_en_US,
                   symbol->name(), base.offset, offset)
               .Attach(object->source,
                   "Incompatible reference to '%s' offset %zd bytes"_en_US,
                   symbol->name(), offset);
         }
       }
     } else {
       dependents_.emplace(*symbol,
           SymbolAndOffset{*base.symbol, base.offset - offset, *object});
     }
   }
 }

 // Offset of this equivalence object from the start of its variable.
 std::size_t ComputeOffsetsHelper::ComputeOffset(
     const EquivalenceObject &object) {
   std::size_t offset{0};
   if (!object.subscripts.empty()) {
     const ArraySpec &shape{object.symbol.get<ObjectEntityDetails>().shape()};
     auto lbound{[&](std::size_t i) {
       return *ToInt64(shape[i].lbound().GetExplicit());
     }};
     auto ubound{[&](std::size_t i) {
       return *ToInt64(shape[i].ubound().GetExplicit());
     }};
     for (std::size_t i{object.subscripts.size() - 1};;) {
       offset += object.subscripts[i] - lbound(i);
       if (i == 0) {
         break;
       }
       --i;
       offset *= ubound(i) - lbound(i) + 1;
     }
   }
   auto result{offset * GetSizeAndAlignment(object.symbol, false).size};
   if (object.substringStart) {
     int kind{context_.defaultKinds().GetDefaultKind(TypeCategory::Character)};
     if (const DeclTypeSpec * type{object.symbol.GetType()}) {
       if (const IntrinsicTypeSpec * intrinsic{type->AsIntrinsic()}) {
         kind = ToInt64(intrinsic->kind()).value_or(kind);
       }
     }
     result += kind * (*object.substringStart - 1);
   }
   return result;
 }

 std::size_t ComputeOffsetsHelper::DoSymbol(Symbol &symbol) {
   if (!symbol.has<ObjectEntityDetails>() && !symbol.has<ProcEntityDetails>()) {
     return 0;
   }
   SizeAndAlignment s{GetSizeAndAlignment(symbol, true)};
   if (s.size == 0) {
     return 0;
   }
   std::size_t previousOffset{offset_};
   offset_ = Align(offset_, s.alignment);
   std::size_t padding{offset_ - previousOffset};
   symbol.set_size(s.size);
   symbol.set_offset(offset_);
   offset_ += s.size;
   alignment_ = std::max(alignment_, s.alignment);
   return padding;
 }

 auto ComputeOffsetsHelper::GetSizeAndAlignment(
     const Symbol &symbol, bool entire) -> SizeAndAlignment {
   auto &targetCharacteristics{context_.targetCharacteristics()};
   if (IsDescriptor(symbol)) {
     auto dyType{evaluate::DynamicType::From(symbol)};
     const auto *derived{evaluate::GetDerivedTypeSpec(dyType)};
     int lenParams{derived ? CountLenParameters(*derived) : 0};
     bool needAddendum{derived || (dyType && dyType->IsUnlimitedPolymorphic())};
     std::size_t size{runtime::Descriptor::SizeInBytes(
         symbol.Rank(), needAddendum, lenParams)};
     return {size, targetCharacteristics.descriptorAlignment()};
   }
   if (IsProcedurePointer(symbol)) {
     return {targetCharacteristics.procedurePointerByteSize(),
         targetCharacteristics.procedurePointerAlignment()};
   }
   if (IsProcedure(symbol)) {
     return {};
   }
   auto &foldingContext{context_.foldingContext()};
   if (auto chars{evaluate::characteristics::TypeAndShape::Characterize(
           symbol, foldingContext)}) {
     if (entire) {
       if (auto size{ToInt64(chars->MeasureSizeInBytes(foldingContext))}) {
         return {static_cast<std::size_t>(*size),
             chars->type().GetAlignment(targetCharacteristics)};
       }
     } else { // element size only
       if (auto size{ToInt64(chars->MeasureElementSizeInBytes(
               foldingContext, true /*aligned*/))}) {
         return {static_cast<std::size_t>(*size),
             chars->type().GetAlignment(targetCharacteristics)};
       }
     }
   }
   return {};
 }

 // Align a size to its natural alignment, up to maxAlignment.
 std::size_t ComputeOffsetsHelper::Align(std::size_t x, std::size_t alignment) {
   alignment =
       std::min(alignment, context_.targetCharacteristics().maxAlignment());
   return (x + alignment - 1) & -alignment;
 }

 void ComputeOffsets(SemanticsContext &context, Scope &scope) {
   ComputeOffsetsHelper{context}.Compute(scope);
 }

 } // namespace Fortran::semantics
	//===-- lib/Semantics/compute-offsets.cpp ------------------------ 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
	//
	//===----------------------------------------------------------------------===//

	#include "compute-offsets.h"
	#include "flang/Evaluate/fold-designator.h"
	#include "flang/Evaluate/fold.h"
	#include "flang/Evaluate/shape.h"
	#include "flang/Evaluate/type.h"
	#include "flang/Runtime/descriptor.h"
	#include "flang/Semantics/scope.h"
	#include "flang/Semantics/semantics.h"
	#include "flang/Semantics/symbol.h"
	#include "flang/Semantics/tools.h"
	#include "flang/Semantics/type.h"
	#include <algorithm>
	#include <vector>

	namespace Fortran::semantics {

	class ComputeOffsetsHelper {
	public:
	ComputeOffsetsHelper(SemanticsContext &context) : context_{context} {}
	void Compute(Scope &);

	private:
	struct SizeAndAlignment {
	SizeAndAlignment() {}
	SizeAndAlignment(std::size_t bytes) : size{bytes}, alignment{bytes} {}
	SizeAndAlignment(std::size_t bytes, std::size_t align)
	: size{bytes}, alignment{align} {}
	std::size_t size{0};
	std::size_t alignment{0};
	};
	struct SymbolAndOffset {
	SymbolAndOffset(Symbol &s, std::size_t off, const EquivalenceObject &obj)
	: symbol{s}, offset{off}, object{&obj} {}
	SymbolAndOffset(const SymbolAndOffset &) = default;
	MutableSymbolRef symbol;
	std::size_t offset;
	const EquivalenceObject *object;
	};

	void DoCommonBlock(Symbol &);
	void DoEquivalenceBlockBase(Symbol &, SizeAndAlignment &);
	void DoEquivalenceSet(const EquivalenceSet &);
	SymbolAndOffset Resolve(const SymbolAndOffset &);
	std::size_t ComputeOffset(const EquivalenceObject &);
	// Returns amount of padding that was needed for alignment
	std::size_t DoSymbol(Symbol &);
	SizeAndAlignment GetSizeAndAlignment(const Symbol &, bool entire);
	std::size_t Align(std::size_t, std::size_t);

	SemanticsContext &context_;
	std::size_t offset_{0};
	std::size_t alignment_{1};
	// symbol -> symbol+offset that determines its location, from EQUIVALENCE
	std::map<MutableSymbolRef, SymbolAndOffset, SymbolAddressCompare> dependents_;
	// base symbol -> SizeAndAlignment for each distinct EQUIVALENCE block
	std::map<MutableSymbolRef, SizeAndAlignment, SymbolAddressCompare>
	equivalenceBlock_;
	};

	void ComputeOffsetsHelper::Compute(Scope &scope) {
	for (Scope &child : scope.children()) {
	ComputeOffsets(context_, child);
	}
	if (scope.symbol() && scope.IsDerivedTypeWithKindParameter()) {
	return; // only process instantiations of kind parameterized derived types
	}
	if (scope.alignment().has_value()) {
	return; // prevent infinite recursion in error cases
	}
	scope.SetAlignment(0);
	// Build dependents_ from equivalences: symbol -> symbol+offset
	for (const EquivalenceSet &set : scope.equivalenceSets()) {
	DoEquivalenceSet(set);
	}
	// Compute a base symbol and overall block size for each
	// disjoint EQUIVALENCE storage sequence.
	for (auto &[symbol, dep] : dependents_) {
	dep = Resolve(dep);
	CHECK(symbol->size() == 0);
	auto symInfo{GetSizeAndAlignment(*symbol, true)};
	symbol->set_size(symInfo.size);
	Symbol &base{*dep.symbol};
	auto iter{equivalenceBlock_.find(base)};
	std::size_t minBlockSize{dep.offset + symInfo.size};
	if (iter == equivalenceBlock_.end()) {
	equivalenceBlock_.emplace(
	base, SizeAndAlignment{minBlockSize, symInfo.alignment});
	} else {
	SizeAndAlignment &blockInfo{iter->second};
	blockInfo.size = std::max(blockInfo.size, minBlockSize);
	blockInfo.alignment = std::max(blockInfo.alignment, symInfo.alignment);
	}
	}
	// Assign offsets for non-COMMON EQUIVALENCE blocks
	for (auto &[symbol, blockInfo] : equivalenceBlock_) {
	if (!FindCommonBlockContaining(*symbol)) {
	DoSymbol(*symbol);
	DoEquivalenceBlockBase(*symbol, blockInfo);
	offset_ = std::max(offset_, symbol->offset() + blockInfo.size);
	}
	}
	// Process remaining non-COMMON symbols; this is all of them if there
	// was no use of EQUIVALENCE in the scope.
	for (auto &symbol : scope.GetSymbols()) {
	if (!FindCommonBlockContaining(*symbol) &&
	dependents_.find(symbol) == dependents_.end() &&
	equivalenceBlock_.find(symbol) == equivalenceBlock_.end()) {
	DoSymbol(*symbol);
	}
	}
	// Ensure that the size is a multiple of the alignment
	offset_ = Align(offset_, alignment_);
	scope.set_size(offset_);
	scope.SetAlignment(alignment_);
	// Assign offsets in COMMON blocks, unless this scope is a BLOCK construct,
	// where COMMON blocks are illegal (C1107 and C1108).
	if (scope.kind() != Scope::Kind::BlockConstruct) {
	for (auto &pair : scope.commonBlocks()) {
	DoCommonBlock(*pair.second);
	}
	}
	for (auto &[symbol, dep] : dependents_) {
	symbol->set_offset(dep.symbol->offset() + dep.offset);
	if (const auto block{FindCommonBlockContaining(dep.symbol)}) {
	symbol->get<ObjectEntityDetails>().set_commonBlock(*block);
	}
	}
	}

	auto ComputeOffsetsHelper::Resolve(const SymbolAndOffset &dep)
	-> SymbolAndOffset {
	auto it{dependents_.find(*dep.symbol)};
	if (it == dependents_.end()) {
	return dep;
	} else {
	SymbolAndOffset result{Resolve(it->second)};
	result.offset += dep.offset;
	result.object = dep.object;
	return result;
	}
	}

	void ComputeOffsetsHelper::DoCommonBlock(Symbol &commonBlock) {
	auto &details{commonBlock.get<CommonBlockDetails>()};
	offset_ = 0;
	alignment_ = 0;
	std::size_t minSize{0};
	std::size_t minAlignment{0};
	UnorderedSymbolSet previous;
	for (auto object : details.objects()) {
	Symbol &symbol{*object};
	auto errorSite{
	commonBlock.name().empty() ? symbol.name() : commonBlock.name()};
	if (std::size_t padding{DoSymbol(symbol.GetUltimate())}) {
	if (context_.ShouldWarn(common::UsageWarning::CommonBlockPadding)) {
	context_.Say(errorSite,
	"COMMON block /%s/ requires %zd bytes of padding before '%s' for alignment"_port_en_US,
	commonBlock.name(), padding, symbol.name());
	}
	}
	previous.emplace(symbol);
	auto eqIter{equivalenceBlock_.end()};
	auto iter{dependents_.find(symbol)};
	if (iter == dependents_.end()) {
	eqIter = equivalenceBlock_.find(symbol);
	if (eqIter != equivalenceBlock_.end()) {
	DoEquivalenceBlockBase(symbol, eqIter->second);
	}
	} else {
	SymbolAndOffset &dep{iter->second};
	Symbol &base{*dep.symbol};
	if (const auto *baseBlock{FindCommonBlockContaining(base)}) {
	if (baseBlock == &commonBlock) {
	if (previous.find(SymbolRef{base}) == previous.end() \|\|
	base.offset() != symbol.offset() - dep.offset) {
	context_.Say(errorSite,
	"'%s' is storage associated with '%s' by EQUIVALENCE elsewhere in COMMON block /%s/"_err_en_US,
	symbol.name(), base.name(), commonBlock.name());
	}
	} else { // F'2023 8.10.3 p1
	context_.Say(errorSite,
	"'%s' in COMMON block /%s/ must not be storage associated with '%s' in COMMON block /%s/ by EQUIVALENCE"_err_en_US,
	symbol.name(), commonBlock.name(), base.name(),
	baseBlock->name());
	}
	} else if (dep.offset > symbol.offset()) { // 8.10.3(3)
	context_.Say(errorSite,
	"'%s' cannot backward-extend COMMON block /%s/ via EQUIVALENCE with '%s'"_err_en_US,
	symbol.name(), commonBlock.name(), base.name());
	} else {
	eqIter = equivalenceBlock_.find(base);
	base.get<ObjectEntityDetails>().set_commonBlock(commonBlock);
	base.set_offset(symbol.offset() - dep.offset);
	previous.emplace(base);
	}
	}
	// Get full extent of any EQUIVALENCE block into size of COMMON ( see
	// 8.10.2.2 point 1 (2))
	if (eqIter != equivalenceBlock_.end()) {
	SizeAndAlignment &blockInfo{eqIter->second};
	minSize = std::max(
	minSize, std::max(offset_, eqIter->first->offset() + blockInfo.size));
	minAlignment = std::max(minAlignment, blockInfo.alignment);
	}
	}
	commonBlock.set_size(std::max(minSize, offset_));
	details.set_alignment(std::max(minAlignment, alignment_));
	context_.MapCommonBlockAndCheckConflicts(commonBlock);
	}

	void ComputeOffsetsHelper::DoEquivalenceBlockBase(
	Symbol &symbol, SizeAndAlignment &blockInfo) {
	if (symbol.size() > blockInfo.size) {
	blockInfo.size = symbol.size();
	}
	}

	void ComputeOffsetsHelper::DoEquivalenceSet(const EquivalenceSet &set) {
	std::vector<SymbolAndOffset> symbolOffsets;
	std::optional<std::size_t> representative;
	for (const EquivalenceObject &object : set) {
	std::size_t offset{ComputeOffset(object)};
	SymbolAndOffset resolved{
	Resolve(SymbolAndOffset{object.symbol, offset, object})};
	symbolOffsets.push_back(resolved);
	if (!representative \|\|
	resolved.offset >= symbolOffsets[*representative].offset) {
	// The equivalenced object with the largest offset from its resolved
	// symbol will be the representative of this set, since the offsets
	// of the other objects will be positive relative to it.
	representative = symbolOffsets.size() - 1;
	}
	}
	CHECK(representative);
	const SymbolAndOffset &base{symbolOffsets[*representative]};
	for (const auto &[symbol, offset, object] : symbolOffsets) {
	if (symbol == base.symbol) {
	if (offset != base.offset) {
	auto x{evaluate::OffsetToDesignator(
	context_.foldingContext(), *symbol, base.offset, 1)};
	auto y{evaluate::OffsetToDesignator(
	context_.foldingContext(), *symbol, offset, 1)};
	if (x && y) {
	context_
	.Say(base.object->source,
	"'%s' and '%s' cannot have the same first storage unit"_err_en_US,
	x->AsFortran(), y->AsFortran())
	.Attach(object->source, "Incompatible reference to '%s'"_en_US,
	y->AsFortran());
	} else { // error recovery
	context_
	.Say(base.object->source,
	"'%s' (offset %zd bytes and %zd bytes) cannot have the same first storage unit"_err_en_US,
	symbol->name(), base.offset, offset)
	.Attach(object->source,
	"Incompatible reference to '%s' offset %zd bytes"_en_US,
	symbol->name(), offset);
	}
	}
	} else {
	dependents_.emplace(*symbol,
	SymbolAndOffset{base.symbol, base.offset - offset, object});
	}
	}
	}

	// Offset of this equivalence object from the start of its variable.
	std::size_t ComputeOffsetsHelper::ComputeOffset(
	const EquivalenceObject &object) {
	std::size_t offset{0};
	if (!object.subscripts.empty()) {
	const ArraySpec &shape{object.symbol.get<ObjectEntityDetails>().shape()};
	auto lbound{[&](std::size_t i) {
	return *ToInt64(shape[i].lbound().GetExplicit());
	}};
	auto ubound{[&](std::size_t i) {
	return *ToInt64(shape[i].ubound().GetExplicit());
	}};
	for (std::size_t i{object.subscripts.size() - 1};;) {
	offset += object.subscripts[i] - lbound(i);
	if (i == 0) {
	break;
	}
	--i;
	offset *= ubound(i) - lbound(i) + 1;
	}
	}
	auto result{offset * GetSizeAndAlignment(object.symbol, false).size};
	if (object.substringStart) {
	int kind{context_.defaultKinds().GetDefaultKind(TypeCategory::Character)};
	if (const DeclTypeSpec * type{object.symbol.GetType()}) {
	if (const IntrinsicTypeSpec * intrinsic{type->AsIntrinsic()}) {
	kind = ToInt64(intrinsic->kind()).value_or(kind);
	}
	}
	result += kind * (*object.substringStart - 1);
	}
	return result;
	}

	std::size_t ComputeOffsetsHelper::DoSymbol(Symbol &symbol) {
	if (!symbol.has<ObjectEntityDetails>() && !symbol.has<ProcEntityDetails>()) {
	return 0;
	}
	SizeAndAlignment s{GetSizeAndAlignment(symbol, true)};
	if (s.size == 0) {
	return 0;
	}
	std::size_t previousOffset{offset_};
	offset_ = Align(offset_, s.alignment);
	std::size_t padding{offset_ - previousOffset};
	symbol.set_size(s.size);
	symbol.set_offset(offset_);
	offset_ += s.size;
	alignment_ = std::max(alignment_, s.alignment);
	return padding;
	}

	auto ComputeOffsetsHelper::GetSizeAndAlignment(
	const Symbol &symbol, bool entire) -> SizeAndAlignment {
	auto &targetCharacteristics{context_.targetCharacteristics()};
	if (IsDescriptor(symbol)) {
	auto dyType{evaluate::DynamicType::From(symbol)};
	const auto *derived{evaluate::GetDerivedTypeSpec(dyType)};
	int lenParams{derived ? CountLenParameters(*derived) : 0};
	bool needAddendum{derived \|\| (dyType && dyType->IsUnlimitedPolymorphic())};
	std::size_t size{runtime::Descriptor::SizeInBytes(
	symbol.Rank(), needAddendum, lenParams)};
	return {size, targetCharacteristics.descriptorAlignment()};
	}
	if (IsProcedurePointer(symbol)) {
	return {targetCharacteristics.procedurePointerByteSize(),
	targetCharacteristics.procedurePointerAlignment()};
	}
	if (IsProcedure(symbol)) {
	return {};
	}
	auto &foldingContext{context_.foldingContext()};
	if (auto chars{evaluate::characteristics::TypeAndShape::Characterize(
	symbol, foldingContext)}) {
	if (entire) {
	if (auto size{ToInt64(chars->MeasureSizeInBytes(foldingContext))}) {
	return {static_cast<std::size_t>(*size),
	chars->type().GetAlignment(targetCharacteristics)};
	}
	} else { // element size only
	if (auto size{ToInt64(chars->MeasureElementSizeInBytes(
	foldingContext, true /aligned/))}) {
	return {static_cast<std::size_t>(*size),
	chars->type().GetAlignment(targetCharacteristics)};
	}
	}
	}
	return {};
	}

	// Align a size to its natural alignment, up to maxAlignment.
	std::size_t ComputeOffsetsHelper::Align(std::size_t x, std::size_t alignment) {
	alignment =
	std::min(alignment, context_.targetCharacteristics().maxAlignment());
	return (x + alignment - 1) & -alignment;
	}

	void ComputeOffsets(SemanticsContext &context, Scope &scope) {
	ComputeOffsetsHelper{context}.Compute(scope);
	}

	} // namespace Fortran::semantics