mlir/lib/IR/Value.cpp - third_party/github.com/llvm/llvm-project - Git at Google

 //===- Value.cpp - MLIR Value Classes -------------------------------------===//
 //
 // Part of the MLIR 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 "mlir/IR/Value.h"
 #include "mlir/IR/Block.h"
 #include "mlir/IR/Operation.h"
 #include "mlir/IR/StandardTypes.h"
 using namespace mlir;

 /// Construct a value.
 Value::Value(detail::BlockArgumentImpl *impl)
     : ownerAndKind(impl, Kind::BlockArgument) {}
 Value::Value(Operation *op, unsigned resultNo) {
   assert(op->getNumResults() > resultNo && "invalid result number");
   if (LLVM_LIKELY(canPackResultInline(resultNo))) {
     ownerAndKind = {op, static_cast<Kind>(resultNo)};
     return;
   }

   // If we can't pack the result directly, we need to represent this as a
   // trailing result.
   unsigned trailingResultNo =
       resultNo - static_cast<unsigned>(Kind::TrailingOpResult);
   ownerAndKind = {op->getTrailingResult(trailingResultNo),
                   Kind::TrailingOpResult};
 }

 /// Return the type of this value.
 Type Value::getType() const {
   if (BlockArgument arg = dyn_cast<BlockArgument>())
     return arg.getType();

   // If this is an operation result, query the parent operation.
   OpResult result = cast<OpResult>();
   Operation *owner = result.getOwner();
   if (owner->hasSingleResult)
     return owner->resultType;
   return owner->resultType.cast<TupleType>().getType(result.getResultNumber());
 }

 /// Mutate the type of this Value to be of the specified type.
 void Value::setType(Type newType) {
   if (BlockArgument arg = dyn_cast<BlockArgument>())
     return arg.setType(newType);
   OpResult result = cast<OpResult>();

   // If the owner has a single result, simply update it directly.
   Operation *owner = result.getOwner();
   if (owner->hasSingleResult) {
     owner->resultType = newType;
     return;
   }
   unsigned resultNo = result.getResultNumber();

   // Otherwise, rebuild the tuple if the new type is different from the current.
   auto curTypes = owner->resultType.cast<TupleType>().getTypes();
   if (curTypes[resultNo] == newType)
     return;
   auto newTypes = llvm::to_vector<4>(curTypes);
   newTypes[resultNo] = newType;
   owner->resultType = TupleType::get(newTypes, newType.getContext());
 }

 /// If this value is the result of an Operation, return the operation that
 /// defines it.
 Operation *Value::getDefiningOp() const {
   if (auto result = dyn_cast<OpResult>())
     return result.getOwner();
   return nullptr;
 }

 Location Value::getLoc() const {
   if (auto *op = getDefiningOp())
     return op->getLoc();
   return UnknownLoc::get(getContext());
 }

 /// Return the Region in which this Value is defined.
 Region *Value::getParentRegion() {
   if (auto *op = getDefiningOp())
     return op->getParentRegion();
   return cast<BlockArgument>().getOwner()->getParent();
 }

 //===----------------------------------------------------------------------===//
 // Value::UseLists
 //===----------------------------------------------------------------------===//

 /// Provide the use list that is attached to this value.
 IRObjectWithUseList<OpOperand> *Value::getUseList() const {
   if (BlockArgument arg = dyn_cast<BlockArgument>())
     return arg.getImpl();
   return cast<OpResult>().getOwner();
 }

 /// Drop all uses of this object from their respective owners.
 void Value::dropAllUses() const {
   if (BlockArgument arg = dyn_cast<BlockArgument>())
     return arg.getImpl()->dropAllUses();
   return cast<OpResult>().getOwner()->dropAllUses(*this);
 }

 /// Replace all uses of 'this' value with the new value, updating anything in
 /// the IR that uses 'this' to use the other value instead.  When this returns
 /// there are zero uses of 'this'.
 void Value::replaceAllUsesWith(Value newValue) const {
   if (BlockArgument arg = dyn_cast<BlockArgument>())
     return arg.getImpl()->replaceAllUsesWith(newValue);
   IRMultiObjectWithUseList<OpOperand> *useList = cast<OpResult>().getOwner();
   useList->replaceAllUsesWith(*this, newValue);
 }

 //===--------------------------------------------------------------------===//
 // Uses

 auto Value::use_begin() const -> use_iterator {
   if (BlockArgument arg = dyn_cast<BlockArgument>())
     return arg.getImpl()->use_begin();
   return cast<OpResult>().getOwner()->use_begin(*this);
 }

 /// Returns true if this value has exactly one use.
 bool Value::hasOneUse() const {
   if (BlockArgument arg = dyn_cast<BlockArgument>())
     return arg.getImpl()->hasOneUse();
   return cast<OpResult>().getOwner()->hasOneUse(*this);
 }

 /// Returns true if this value has no uses.
 bool Value::use_empty() const {
   if (BlockArgument arg = dyn_cast<BlockArgument>())
     return arg.getImpl()->use_empty();
   return cast<OpResult>().getOwner()->use_empty(*this);
 }

 //===----------------------------------------------------------------------===//
 // OpResult
 //===----------------------------------------------------------------------===//

 /// Returns the operation that owns this result.
 Operation *OpResult::getOwner() const {
   // If the result is in-place, the `owner` is the operation.
   if (LLVM_LIKELY(getKind() != Kind::TrailingOpResult))
     return reinterpret_cast<Operation *>(ownerAndKind.getPointer());

   // Otherwise, we need to do some arithmetic to get the operation pointer.
   // Move the trailing owner to the start of the array.
   auto *trailingIt =
       static_cast<detail::TrailingOpResult *>(ownerAndKind.getPointer());
   trailingIt -= trailingIt->trailingResultNumber;

   // This point is the first trailing object after the operation. So all we need
   // to do here is adjust for the operation size.
   return reinterpret_cast<Operation *>(trailingIt) - 1;
 }

 /// Return the result number of this result.
 unsigned OpResult::getResultNumber() const {
   // If the result is in-place, we can use the kind directly.
   if (LLVM_LIKELY(getKind() != Kind::TrailingOpResult))
     return static_cast<unsigned>(ownerAndKind.getInt());
   // Otherwise, we add the number of inline results to the trailing owner.
   auto *trailingIt =
       static_cast<detail::TrailingOpResult *>(ownerAndKind.getPointer());
   unsigned trailingNumber = trailingIt->trailingResultNumber;
   return trailingNumber + static_cast<unsigned>(Kind::TrailingOpResult);
 }

 /// Given a number of operation results, returns the number that need to be
 /// stored as trailing.
 unsigned OpResult::getNumTrailing(unsigned numResults) {
   // If we can pack all of the results, there is no need for additional storage.
   if (numResults <= static_cast<unsigned>(Kind::TrailingOpResult))
     return 0;
   return numResults - static_cast<unsigned>(Kind::TrailingOpResult);
 }

 //===----------------------------------------------------------------------===//
 // BlockOperand
 //===----------------------------------------------------------------------===//

 /// Provide the use list that is attached to the given block.
 IRObjectWithUseList<BlockOperand> *BlockOperand::getUseList(Block *value) {
   return value;
 }

 /// Return which operand this is in the operand list.
 unsigned BlockOperand::getOperandNumber() {
   return this - &getOwner()->getBlockOperands()[0];
 }

 //===----------------------------------------------------------------------===//
 // OpOperand
 //===----------------------------------------------------------------------===//

 /// Provide the use list that is attached to the given value.
 IRObjectWithUseList<OpOperand> *OpOperand::getUseList(Value value) {
   return value.getUseList();
 }

 /// Return the current value being used by this operand.
 Value OpOperand::get() const {
   return IROperand<OpOperand, detail::OpaqueValue>::get();
 }

 /// Set the operand to the given value.
 void OpOperand::set(Value value) {
   IROperand<OpOperand, detail::OpaqueValue>::set(value);
 }

 /// Return which operand this is in the operand list.
 unsigned OpOperand::getOperandNumber() {
   return this - &getOwner()->getOpOperands()[0];
 }

 //===----------------------------------------------------------------------===//
 // detail::OpaqueValue
 //===----------------------------------------------------------------------===//

 /// Implicit conversion from 'Value'.
 detail::OpaqueValue::OpaqueValue(Value value)
     : impl(value.getAsOpaquePointer()) {}

 /// Implicit conversion back to 'Value'.
 detail::OpaqueValue::operator Value() const {
   return Value::getFromOpaquePointer(impl);
 }
	//===- Value.cpp - MLIR Value Classes -------------------------------------===//
	//
	// Part of the MLIR 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 "mlir/IR/Value.h"
	#include "mlir/IR/Block.h"
	#include "mlir/IR/Operation.h"
	#include "mlir/IR/StandardTypes.h"
	using namespace mlir;

	/// Construct a value.
	Value::Value(detail::BlockArgumentImpl *impl)
	: ownerAndKind(impl, Kind::BlockArgument) {}
	Value::Value(Operation *op, unsigned resultNo) {
	assert(op->getNumResults() > resultNo && "invalid result number");
	if (LLVM_LIKELY(canPackResultInline(resultNo))) {
	ownerAndKind = {op, static_cast<Kind>(resultNo)};
	return;
	}

	// If we can't pack the result directly, we need to represent this as a
	// trailing result.
	unsigned trailingResultNo =
	resultNo - static_cast<unsigned>(Kind::TrailingOpResult);
	ownerAndKind = {op->getTrailingResult(trailingResultNo),
	Kind::TrailingOpResult};
	}

	/// Return the type of this value.
	Type Value::getType() const {
	if (BlockArgument arg = dyn_cast<BlockArgument>())
	return arg.getType();

	// If this is an operation result, query the parent operation.
	OpResult result = cast<OpResult>();
	Operation *owner = result.getOwner();
	if (owner->hasSingleResult)
	return owner->resultType;
	return owner->resultType.cast<TupleType>().getType(result.getResultNumber());
	}

	/// Mutate the type of this Value to be of the specified type.
	void Value::setType(Type newType) {
	if (BlockArgument arg = dyn_cast<BlockArgument>())
	return arg.setType(newType);
	OpResult result = cast<OpResult>();

	// If the owner has a single result, simply update it directly.
	Operation *owner = result.getOwner();
	if (owner->hasSingleResult) {
	owner->resultType = newType;
	return;
	}
	unsigned resultNo = result.getResultNumber();

	// Otherwise, rebuild the tuple if the new type is different from the current.
	auto curTypes = owner->resultType.cast<TupleType>().getTypes();
	if (curTypes[resultNo] == newType)
	return;
	auto newTypes = llvm::to_vector<4>(curTypes);
	newTypes[resultNo] = newType;
	owner->resultType = TupleType::get(newTypes, newType.getContext());
	}

	/// If this value is the result of an Operation, return the operation that
	/// defines it.
	Operation *Value::getDefiningOp() const {
	if (auto result = dyn_cast<OpResult>())
	return result.getOwner();
	return nullptr;
	}

	Location Value::getLoc() const {
	if (auto *op = getDefiningOp())
	return op->getLoc();
	return UnknownLoc::get(getContext());
	}

	/// Return the Region in which this Value is defined.
	Region *Value::getParentRegion() {
	if (auto *op = getDefiningOp())
	return op->getParentRegion();
	return cast<BlockArgument>().getOwner()->getParent();
	}

	//===----------------------------------------------------------------------===//
	// Value::UseLists
	//===----------------------------------------------------------------------===//

	/// Provide the use list that is attached to this value.
	IRObjectWithUseList<OpOperand> *Value::getUseList() const {
	if (BlockArgument arg = dyn_cast<BlockArgument>())
	return arg.getImpl();
	return cast<OpResult>().getOwner();
	}

	/// Drop all uses of this object from their respective owners.
	void Value::dropAllUses() const {
	if (BlockArgument arg = dyn_cast<BlockArgument>())
	return arg.getImpl()->dropAllUses();
	return cast<OpResult>().getOwner()->dropAllUses(*this);
	}

	/// Replace all uses of 'this' value with the new value, updating anything in
	/// the IR that uses 'this' to use the other value instead. When this returns
	/// there are zero uses of 'this'.
	void Value::replaceAllUsesWith(Value newValue) const {
	if (BlockArgument arg = dyn_cast<BlockArgument>())
	return arg.getImpl()->replaceAllUsesWith(newValue);
	IRMultiObjectWithUseList<OpOperand> *useList = cast<OpResult>().getOwner();
	useList->replaceAllUsesWith(*this, newValue);
	}

	//===--------------------------------------------------------------------===//
	// Uses

	auto Value::use_begin() const -> use_iterator {
	if (BlockArgument arg = dyn_cast<BlockArgument>())
	return arg.getImpl()->use_begin();
	return cast<OpResult>().getOwner()->use_begin(*this);
	}

	/// Returns true if this value has exactly one use.
	bool Value::hasOneUse() const {
	if (BlockArgument arg = dyn_cast<BlockArgument>())
	return arg.getImpl()->hasOneUse();
	return cast<OpResult>().getOwner()->hasOneUse(*this);
	}

	/// Returns true if this value has no uses.
	bool Value::use_empty() const {
	if (BlockArgument arg = dyn_cast<BlockArgument>())
	return arg.getImpl()->use_empty();
	return cast<OpResult>().getOwner()->use_empty(*this);
	}

	//===----------------------------------------------------------------------===//
	// OpResult
	//===----------------------------------------------------------------------===//

	/// Returns the operation that owns this result.
	Operation *OpResult::getOwner() const {
	// If the result is in-place, the `owner` is the operation.
	if (LLVM_LIKELY(getKind() != Kind::TrailingOpResult))
	return reinterpret_cast<Operation *>(ownerAndKind.getPointer());

	// Otherwise, we need to do some arithmetic to get the operation pointer.
	// Move the trailing owner to the start of the array.
	auto *trailingIt =
	static_cast<detail::TrailingOpResult *>(ownerAndKind.getPointer());
	trailingIt -= trailingIt->trailingResultNumber;

	// This point is the first trailing object after the operation. So all we need
	// to do here is adjust for the operation size.
	return reinterpret_cast<Operation *>(trailingIt) - 1;
	}

	/// Return the result number of this result.
	unsigned OpResult::getResultNumber() const {
	// If the result is in-place, we can use the kind directly.
	if (LLVM_LIKELY(getKind() != Kind::TrailingOpResult))
	return static_cast<unsigned>(ownerAndKind.getInt());
	// Otherwise, we add the number of inline results to the trailing owner.
	auto *trailingIt =
	static_cast<detail::TrailingOpResult *>(ownerAndKind.getPointer());
	unsigned trailingNumber = trailingIt->trailingResultNumber;
	return trailingNumber + static_cast<unsigned>(Kind::TrailingOpResult);
	}

	/// Given a number of operation results, returns the number that need to be
	/// stored as trailing.
	unsigned OpResult::getNumTrailing(unsigned numResults) {
	// If we can pack all of the results, there is no need for additional storage.
	if (numResults <= static_cast<unsigned>(Kind::TrailingOpResult))
	return 0;
	return numResults - static_cast<unsigned>(Kind::TrailingOpResult);
	}

	//===----------------------------------------------------------------------===//
	// BlockOperand
	//===----------------------------------------------------------------------===//

	/// Provide the use list that is attached to the given block.
	IRObjectWithUseList<BlockOperand> BlockOperand::getUseList(Block value) {
	return value;
	}

	/// Return which operand this is in the operand list.
	unsigned BlockOperand::getOperandNumber() {
	return this - &getOwner()->getBlockOperands()[0];
	}

	//===----------------------------------------------------------------------===//
	// OpOperand
	//===----------------------------------------------------------------------===//

	/// Provide the use list that is attached to the given value.
	IRObjectWithUseList<OpOperand> *OpOperand::getUseList(Value value) {
	return value.getUseList();
	}

	/// Return the current value being used by this operand.
	Value OpOperand::get() const {
	return IROperand<OpOperand, detail::OpaqueValue>::get();
	}

	/// Set the operand to the given value.
	void OpOperand::set(Value value) {
	IROperand<OpOperand, detail::OpaqueValue>::set(value);
	}

	/// Return which operand this is in the operand list.
	unsigned OpOperand::getOperandNumber() {
	return this - &getOwner()->getOpOperands()[0];
	}

	//===----------------------------------------------------------------------===//
	// detail::OpaqueValue
	//===----------------------------------------------------------------------===//

	/// Implicit conversion from 'Value'.
	detail::OpaqueValue::OpaqueValue(Value value)
	: impl(value.getAsOpaquePointer()) {}

	/// Implicit conversion back to 'Value'.
	detail::OpaqueValue::operator Value() const {
	return Value::getFromOpaquePointer(impl);
	}