mlir/lib/TableGen/Predicate.cpp - llvm-project - Git at Google

 //===- Predicate.cpp - Predicate class ------------------------------------===//
 //
 // 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
 //
 //===----------------------------------------------------------------------===//
 //
 // Wrapper around predicates defined in TableGen.
 //
 //===----------------------------------------------------------------------===//

 #include "mlir/TableGen/Predicate.h"
 #include "llvm/ADT/SetVector.h"
 #include "llvm/ADT/SmallPtrSet.h"
 #include "llvm/ADT/StringExtras.h"
 #include "llvm/Support/FormatVariadic.h"
 #include "llvm/TableGen/Error.h"
 #include "llvm/TableGen/Record.h"

 using namespace mlir;
 using namespace tblgen;

 // Construct a Predicate from a record.
 Pred::Pred(const llvm::Record *record) : def(record) {
   assert(def->isSubClassOf("Pred") &&
          "must be a subclass of TableGen 'Pred' class");
 }

 // Construct a Predicate from an initializer.
 Pred::Pred(const llvm::Init *init) : def(nullptr) {
   if (const auto *defInit = dyn_cast_or_null<llvm::DefInit>(init))
     def = defInit->getDef();
 }

 std::string Pred::getCondition() const {
   // Static dispatch to subclasses.
   if (def->isSubClassOf("CombinedPred"))
     return static_cast<const CombinedPred *>(this)->getConditionImpl();
   if (def->isSubClassOf("CPred"))
     return static_cast<const CPred *>(this)->getConditionImpl();
   llvm_unreachable("Pred::getCondition must be overridden in subclasses");
 }

 bool Pred::isCombined() const {
   return def && def->isSubClassOf("CombinedPred");
 }

 ArrayRef<llvm::SMLoc> Pred::getLoc() const { return def->getLoc(); }

 CPred::CPred(const llvm::Record *record) : Pred(record) {
   assert(def->isSubClassOf("CPred") &&
          "must be a subclass of Tablegen 'CPred' class");
 }

 CPred::CPred(const llvm::Init *init) : Pred(init) {
   assert((!def || def->isSubClassOf("CPred")) &&
          "must be a subclass of Tablegen 'CPred' class");
 }

 // Get condition of the C Predicate.
 std::string CPred::getConditionImpl() const {
   assert(!isNull() && "null predicate does not have a condition");
   return std::string(def->getValueAsString("predExpr"));
 }

 CombinedPred::CombinedPred(const llvm::Record *record) : Pred(record) {
   assert(def->isSubClassOf("CombinedPred") &&
          "must be a subclass of Tablegen 'CombinedPred' class");
 }

 CombinedPred::CombinedPred(const llvm::Init *init) : Pred(init) {
   assert((!def || def->isSubClassOf("CombinedPred")) &&
          "must be a subclass of Tablegen 'CombinedPred' class");
 }

 const llvm::Record *CombinedPred::getCombinerDef() const {
   assert(def->getValue("kind") && "CombinedPred must have a value 'kind'");
   return def->getValueAsDef("kind");
 }

 const std::vector<llvm::Record *> CombinedPred::getChildren() const {
   assert(def->getValue("children") &&
          "CombinedPred must have a value 'children'");
   return def->getValueAsListOfDefs("children");
 }

 namespace {
 // Kinds of nodes in a logical predicate tree.
 enum class PredCombinerKind {
   Leaf,
   And,
   Or,
   Not,
   SubstLeaves,
   Concat,
   // Special kinds that are used in simplification.
   False,
   True
 };

 // A node in a logical predicate tree.
 struct PredNode {
   PredCombinerKind kind;
   const Pred *predicate;
   SmallVector<PredNode *, 4> children;
   std::string expr;

   // Prefix and suffix are used by ConcatPred.
   std::string prefix;
   std::string suffix;
 };
 } // end anonymous namespace

 // Get a predicate tree node kind based on the kind used in the predicate
 // TableGen record.
 static PredCombinerKind getPredCombinerKind(const Pred &pred) {
   if (!pred.isCombined())
     return PredCombinerKind::Leaf;

   const auto &combinedPred = static_cast<const CombinedPred &>(pred);
   return StringSwitch<PredCombinerKind>(
              combinedPred.getCombinerDef()->getName())
       .Case("PredCombinerAnd", PredCombinerKind::And)
       .Case("PredCombinerOr", PredCombinerKind::Or)
       .Case("PredCombinerNot", PredCombinerKind::Not)
       .Case("PredCombinerSubstLeaves", PredCombinerKind::SubstLeaves)
       .Case("PredCombinerConcat", PredCombinerKind::Concat);
 }

 namespace {
 // Substitution<pattern, replacement>.
 using Subst = std::pair<StringRef, StringRef>;
 } // end anonymous namespace

 /// Perform the given substitutions on 'str' in-place.
 static void performSubstitutions(std::string &str,
                                  ArrayRef<Subst> substitutions) {
   // Apply all parent substitutions from innermost to outermost.
   for (const auto &subst : llvm::reverse(substitutions)) {
     auto pos = str.find(std::string(subst.first));
     while (pos != std::string::npos) {
       str.replace(pos, subst.first.size(), std::string(subst.second));
       // Skip the newly inserted substring, which itself may consider the
       // pattern to match.
       pos += subst.second.size();
       // Find the next possible match position.
       pos = str.find(std::string(subst.first), pos);
     }
   }
 }

 // Build the predicate tree starting from the top-level predicate, which may
 // have children, and perform leaf substitutions inplace.  Note that after
 // substitution, nodes are still pointing to the original TableGen record.
 // All nodes are created within "allocator".
 static PredNode *
 buildPredicateTree(const Pred &root,
                    llvm::SpecificBumpPtrAllocator<PredNode> &allocator,
                    ArrayRef<Subst> substitutions) {
   auto *rootNode = allocator.Allocate();
   new (rootNode) PredNode;
   rootNode->kind = getPredCombinerKind(root);
   rootNode->predicate = &root;
   if (!root.isCombined()) {
     rootNode->expr = root.getCondition();
     performSubstitutions(rootNode->expr, substitutions);
     return rootNode;
   }

   // If the current combined predicate is a leaf substitution, append it to the
   // list before continuing.
   auto allSubstitutions = llvm::to_vector<4>(substitutions);
   if (rootNode->kind == PredCombinerKind::SubstLeaves) {
     const auto &substPred = static_cast<const SubstLeavesPred &>(root);
     allSubstitutions.push_back(
         {substPred.getPattern(), substPred.getReplacement()});

     // If the current predicate is a ConcatPred, record the prefix and suffix.
   } else if (rootNode->kind == PredCombinerKind::Concat) {
     const auto &concatPred = static_cast<const ConcatPred &>(root);
     rootNode->prefix = std::string(concatPred.getPrefix());
     performSubstitutions(rootNode->prefix, substitutions);
     rootNode->suffix = std::string(concatPred.getSuffix());
     performSubstitutions(rootNode->suffix, substitutions);
   }

   // Build child subtrees.
   auto combined = static_cast<const CombinedPred &>(root);
   for (const auto *record : combined.getChildren()) {
     auto childTree =
         buildPredicateTree(Pred(record), allocator, allSubstitutions);
     rootNode->children.push_back(childTree);
   }
   return rootNode;
 }

 // Simplify a predicate tree rooted at "node" using the predicates that are
 // known to be true(false).  For AND(OR) combined predicates, if any of the
 // children is known to be false(true), the result is also false(true).
 // Furthermore, for AND(OR) combined predicates, children that are known to be
 // true(false) don't have to be checked dynamically.
 static PredNode *
 propagateGroundTruth(PredNode *node,
                      const llvm::SmallPtrSetImpl<Pred *> &knownTruePreds,
                      const llvm::SmallPtrSetImpl<Pred *> &knownFalsePreds) {
   // If the current predicate is known to be true or false, change the kind of
   // the node and return immediately.
   if (knownTruePreds.count(node->predicate) != 0) {
     node->kind = PredCombinerKind::True;
     node->children.clear();
     return node;
   }
   if (knownFalsePreds.count(node->predicate) != 0) {
     node->kind = PredCombinerKind::False;
     node->children.clear();
     return node;
   }

   // If the current node is a substitution, stop recursion now.
   // The expressions in the leaves below this node were rewritten, but the nodes
   // still point to the original predicate records.  While the original
   // predicate may be known to be true or false, it is not necessarily the case
   // after rewriting.
   // TODO: we can support ground truth for rewritten
   // predicates by either (a) having our own unique'ing of the predicates
   // instead of relying on TableGen record pointers or (b) taking ground truth
   // values optionally prefixed with a list of substitutions to apply, e.g.
   // "predX is true by itself as well as predSubY leaf substitution had been
   // applied to it".
   if (node->kind == PredCombinerKind::SubstLeaves) {
     return node;
   }

   // Otherwise, look at child nodes.

   // Move child nodes into some local variable so that they can be optimized
   // separately and re-added if necessary.
   llvm::SmallVector<PredNode *, 4> children;
   std::swap(node->children, children);

   for (auto &child : children) {
     // First, simplify the child.  This maintains the predicate as it was.
     auto simplifiedChild =
         propagateGroundTruth(child, knownTruePreds, knownFalsePreds);

     // Just add the child if we don't know how to simplify the current node.
     if (node->kind != PredCombinerKind::And &&
         node->kind != PredCombinerKind::Or) {
       node->children.push_back(simplifiedChild);
       continue;
     }

     // Second, based on the type define which known values of child predicates
     // immediately collapse this predicate to a known value, and which others
     // may be safely ignored.
     //   OR(..., True, ...) = True
     //   OR(..., False, ...) = OR(..., ...)
     //   AND(..., False, ...) = False
     //   AND(..., True, ...) = AND(..., ...)
     auto collapseKind = node->kind == PredCombinerKind::And
                             ? PredCombinerKind::False
                             : PredCombinerKind::True;
     auto eraseKind = node->kind == PredCombinerKind::And
                          ? PredCombinerKind::True
                          : PredCombinerKind::False;
     const auto &collapseList =
         node->kind == PredCombinerKind::And ? knownFalsePreds : knownTruePreds;
     const auto &eraseList =
         node->kind == PredCombinerKind::And ? knownTruePreds : knownFalsePreds;
     if (simplifiedChild->kind == collapseKind ||
         collapseList.count(simplifiedChild->predicate) != 0) {
       node->kind = collapseKind;
       node->children.clear();
       return node;
     } else if (simplifiedChild->kind == eraseKind ||
                eraseList.count(simplifiedChild->predicate) != 0) {
       continue;
     }
     node->children.push_back(simplifiedChild);
   }
   return node;
 }

 // Combine a list of predicate expressions using a binary combiner.  If a list
 // is empty, return "init".
 static std::string combineBinary(ArrayRef<std::string> children,
                                  std::string combiner, std::string init) {
   if (children.empty())
     return init;

   auto size = children.size();
   if (size == 1)
     return children.front();

   std::string str;
   llvm::raw_string_ostream os(str);
   os << '(' << children.front() << ')';
   for (unsigned i = 1; i < size; ++i) {
     os << ' ' << combiner << " (" << children[i] << ')';
   }
   return os.str();
 }

 // Prepend negation to the only condition in the predicate expression list.
 static std::string combineNot(ArrayRef<std::string> children) {
   assert(children.size() == 1 && "expected exactly one child predicate of Neg");
   return (Twine("!(") + children.front() + Twine(')')).str();
 }

 // Recursively traverse the predicate tree in depth-first post-order and build
 // the final expression.
 static std::string getCombinedCondition(const PredNode &root) {
   // Immediately return for non-combiner predicates that don't have children.
   if (root.kind == PredCombinerKind::Leaf)
     return root.expr;
   if (root.kind == PredCombinerKind::True)
     return "true";
   if (root.kind == PredCombinerKind::False)
     return "false";

   // Recurse into children.
   llvm::SmallVector<std::string, 4> childExpressions;
   childExpressions.reserve(root.children.size());
   for (const auto &child : root.children)
     childExpressions.push_back(getCombinedCondition(*child));

   // Combine the expressions based on the predicate node kind.
   if (root.kind == PredCombinerKind::And)
     return combineBinary(childExpressions, "&&", "true");
   if (root.kind == PredCombinerKind::Or)
     return combineBinary(childExpressions, "||", "false");
   if (root.kind == PredCombinerKind::Not)
     return combineNot(childExpressions);
   if (root.kind == PredCombinerKind::Concat) {
     assert(childExpressions.size() == 1 &&
            "ConcatPred should only have one child");
     return root.prefix + childExpressions.front() + root.suffix;
   }

   // Substitutions were applied before so just ignore them.
   if (root.kind == PredCombinerKind::SubstLeaves) {
     assert(childExpressions.size() == 1 &&
            "substitution predicate must have one child");
     return childExpressions[0];
   }

   llvm::PrintFatalError(root.predicate->getLoc(), "unsupported predicate kind");
 }

 std::string CombinedPred::getConditionImpl() const {
   llvm::SpecificBumpPtrAllocator<PredNode> allocator;
   auto predicateTree = buildPredicateTree(*this, allocator, {});
   predicateTree =
       propagateGroundTruth(predicateTree,
                            /*knownTruePreds=*/llvm::SmallPtrSet<Pred *, 2>(),
                            /*knownFalsePreds=*/llvm::SmallPtrSet<Pred *, 2>());

   return getCombinedCondition(*predicateTree);
 }

 StringRef SubstLeavesPred::getPattern() const {
   return def->getValueAsString("pattern");
 }

 StringRef SubstLeavesPred::getReplacement() const {
   return def->getValueAsString("replacement");
 }

 StringRef ConcatPred::getPrefix() const {
   return def->getValueAsString("prefix");
 }

 StringRef ConcatPred::getSuffix() const {
   return def->getValueAsString("suffix");
 }
	//===- Predicate.cpp - Predicate class ------------------------------------===//
	//
	// 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
	//
	//===----------------------------------------------------------------------===//
	//
	// Wrapper around predicates defined in TableGen.
	//
	//===----------------------------------------------------------------------===//

	#include "mlir/TableGen/Predicate.h"
	#include "llvm/ADT/SetVector.h"
	#include "llvm/ADT/SmallPtrSet.h"
	#include "llvm/ADT/StringExtras.h"
	#include "llvm/Support/FormatVariadic.h"
	#include "llvm/TableGen/Error.h"
	#include "llvm/TableGen/Record.h"

	using namespace mlir;
	using namespace tblgen;

	// Construct a Predicate from a record.
	Pred::Pred(const llvm::Record *record) : def(record) {
	assert(def->isSubClassOf("Pred") &&
	"must be a subclass of TableGen 'Pred' class");
	}

	// Construct a Predicate from an initializer.
	Pred::Pred(const llvm::Init *init) : def(nullptr) {
	if (const auto *defInit = dyn_cast_or_null<llvm::DefInit>(init))
	def = defInit->getDef();
	}

	std::string Pred::getCondition() const {
	// Static dispatch to subclasses.
	if (def->isSubClassOf("CombinedPred"))
	return static_cast<const CombinedPred *>(this)->getConditionImpl();
	if (def->isSubClassOf("CPred"))
	return static_cast<const CPred *>(this)->getConditionImpl();
	llvm_unreachable("Pred::getCondition must be overridden in subclasses");
	}

	bool Pred::isCombined() const {
	return def && def->isSubClassOf("CombinedPred");
	}

	ArrayRef<llvm::SMLoc> Pred::getLoc() const { return def->getLoc(); }

	CPred::CPred(const llvm::Record *record) : Pred(record) {
	assert(def->isSubClassOf("CPred") &&
	"must be a subclass of Tablegen 'CPred' class");
	}

	CPred::CPred(const llvm::Init *init) : Pred(init) {
	assert((!def \|\| def->isSubClassOf("CPred")) &&
	"must be a subclass of Tablegen 'CPred' class");
	}

	// Get condition of the C Predicate.
	std::string CPred::getConditionImpl() const {
	assert(!isNull() && "null predicate does not have a condition");
	return std::string(def->getValueAsString("predExpr"));
	}

	CombinedPred::CombinedPred(const llvm::Record *record) : Pred(record) {
	assert(def->isSubClassOf("CombinedPred") &&
	"must be a subclass of Tablegen 'CombinedPred' class");
	}

	CombinedPred::CombinedPred(const llvm::Init *init) : Pred(init) {
	assert((!def \|\| def->isSubClassOf("CombinedPred")) &&
	"must be a subclass of Tablegen 'CombinedPred' class");
	}

	const llvm::Record *CombinedPred::getCombinerDef() const {
	assert(def->getValue("kind") && "CombinedPred must have a value 'kind'");
	return def->getValueAsDef("kind");
	}

	const std::vector<llvm::Record *> CombinedPred::getChildren() const {
	assert(def->getValue("children") &&
	"CombinedPred must have a value 'children'");
	return def->getValueAsListOfDefs("children");
	}

	namespace {
	// Kinds of nodes in a logical predicate tree.
	enum class PredCombinerKind {
	Leaf,
	And,
	Or,
	Not,
	SubstLeaves,
	Concat,
	// Special kinds that are used in simplification.
	False,
	True
	};

	// A node in a logical predicate tree.
	struct PredNode {
	PredCombinerKind kind;
	const Pred *predicate;
	SmallVector<PredNode *, 4> children;
	std::string expr;

	// Prefix and suffix are used by ConcatPred.
	std::string prefix;
	std::string suffix;
	};
	} // end anonymous namespace

	// Get a predicate tree node kind based on the kind used in the predicate
	// TableGen record.
	static PredCombinerKind getPredCombinerKind(const Pred &pred) {
	if (!pred.isCombined())
	return PredCombinerKind::Leaf;

	const auto &combinedPred = static_cast<const CombinedPred &>(pred);
	return StringSwitch<PredCombinerKind>(
	combinedPred.getCombinerDef()->getName())
	.Case("PredCombinerAnd", PredCombinerKind::And)
	.Case("PredCombinerOr", PredCombinerKind::Or)
	.Case("PredCombinerNot", PredCombinerKind::Not)
	.Case("PredCombinerSubstLeaves", PredCombinerKind::SubstLeaves)
	.Case("PredCombinerConcat", PredCombinerKind::Concat);
	}

	namespace {
	// Substitution<pattern, replacement>.
	using Subst = std::pair<StringRef, StringRef>;
	} // end anonymous namespace

	/// Perform the given substitutions on 'str' in-place.
	static void performSubstitutions(std::string &str,
	ArrayRef<Subst> substitutions) {
	// Apply all parent substitutions from innermost to outermost.
	for (const auto &subst : llvm::reverse(substitutions)) {
	auto pos = str.find(std::string(subst.first));
	while (pos != std::string::npos) {
	str.replace(pos, subst.first.size(), std::string(subst.second));
	// Skip the newly inserted substring, which itself may consider the
	// pattern to match.
	pos += subst.second.size();
	// Find the next possible match position.
	pos = str.find(std::string(subst.first), pos);
	}
	}
	}

	// Build the predicate tree starting from the top-level predicate, which may
	// have children, and perform leaf substitutions inplace. Note that after
	// substitution, nodes are still pointing to the original TableGen record.
	// All nodes are created within "allocator".
	static PredNode *
	buildPredicateTree(const Pred &root,
	llvm::SpecificBumpPtrAllocator<PredNode> &allocator,
	ArrayRef<Subst> substitutions) {
	auto *rootNode = allocator.Allocate();
	new (rootNode) PredNode;
	rootNode->kind = getPredCombinerKind(root);
	rootNode->predicate = &root;
	if (!root.isCombined()) {
	rootNode->expr = root.getCondition();
	performSubstitutions(rootNode->expr, substitutions);
	return rootNode;
	}

	// If the current combined predicate is a leaf substitution, append it to the
	// list before continuing.
	auto allSubstitutions = llvm::to_vector<4>(substitutions);
	if (rootNode->kind == PredCombinerKind::SubstLeaves) {
	const auto &substPred = static_cast<const SubstLeavesPred &>(root);
	allSubstitutions.push_back(
	{substPred.getPattern(), substPred.getReplacement()});

	// If the current predicate is a ConcatPred, record the prefix and suffix.
	} else if (rootNode->kind == PredCombinerKind::Concat) {
	const auto &concatPred = static_cast<const ConcatPred &>(root);
	rootNode->prefix = std::string(concatPred.getPrefix());
	performSubstitutions(rootNode->prefix, substitutions);
	rootNode->suffix = std::string(concatPred.getSuffix());
	performSubstitutions(rootNode->suffix, substitutions);
	}

	// Build child subtrees.
	auto combined = static_cast<const CombinedPred &>(root);
	for (const auto *record : combined.getChildren()) {
	auto childTree =
	buildPredicateTree(Pred(record), allocator, allSubstitutions);
	rootNode->children.push_back(childTree);
	}
	return rootNode;
	}

	// Simplify a predicate tree rooted at "node" using the predicates that are
	// known to be true(false). For AND(OR) combined predicates, if any of the
	// children is known to be false(true), the result is also false(true).
	// Furthermore, for AND(OR) combined predicates, children that are known to be
	// true(false) don't have to be checked dynamically.
	static PredNode *
	propagateGroundTruth(PredNode *node,
	const llvm::SmallPtrSetImpl<Pred *> &knownTruePreds,
	const llvm::SmallPtrSetImpl<Pred *> &knownFalsePreds) {
	// If the current predicate is known to be true or false, change the kind of
	// the node and return immediately.
	if (knownTruePreds.count(node->predicate) != 0) {
	node->kind = PredCombinerKind::True;
	node->children.clear();
	return node;
	}
	if (knownFalsePreds.count(node->predicate) != 0) {
	node->kind = PredCombinerKind::False;
	node->children.clear();
	return node;
	}

	// If the current node is a substitution, stop recursion now.
	// The expressions in the leaves below this node were rewritten, but the nodes
	// still point to the original predicate records. While the original
	// predicate may be known to be true or false, it is not necessarily the case
	// after rewriting.
	// TODO: we can support ground truth for rewritten
	// predicates by either (a) having our own unique'ing of the predicates
	// instead of relying on TableGen record pointers or (b) taking ground truth
	// values optionally prefixed with a list of substitutions to apply, e.g.
	// "predX is true by itself as well as predSubY leaf substitution had been
	// applied to it".
	if (node->kind == PredCombinerKind::SubstLeaves) {
	return node;
	}

	// Otherwise, look at child nodes.

	// Move child nodes into some local variable so that they can be optimized
	// separately and re-added if necessary.
	llvm::SmallVector<PredNode *, 4> children;
	std::swap(node->children, children);

	for (auto &child : children) {
	// First, simplify the child. This maintains the predicate as it was.
	auto simplifiedChild =
	propagateGroundTruth(child, knownTruePreds, knownFalsePreds);

	// Just add the child if we don't know how to simplify the current node.
	if (node->kind != PredCombinerKind::And &&
	node->kind != PredCombinerKind::Or) {
	node->children.push_back(simplifiedChild);
	continue;
	}

	// Second, based on the type define which known values of child predicates
	// immediately collapse this predicate to a known value, and which others
	// may be safely ignored.
	// OR(..., True, ...) = True
	// OR(..., False, ...) = OR(..., ...)
	// AND(..., False, ...) = False
	// AND(..., True, ...) = AND(..., ...)
	auto collapseKind = node->kind == PredCombinerKind::And
	? PredCombinerKind::False
	: PredCombinerKind::True;
	auto eraseKind = node->kind == PredCombinerKind::And
	? PredCombinerKind::True
	: PredCombinerKind::False;
	const auto &collapseList =
	node->kind == PredCombinerKind::And ? knownFalsePreds : knownTruePreds;
	const auto &eraseList =
	node->kind == PredCombinerKind::And ? knownTruePreds : knownFalsePreds;
	if (simplifiedChild->kind == collapseKind \|\|
	collapseList.count(simplifiedChild->predicate) != 0) {
	node->kind = collapseKind;
	node->children.clear();
	return node;
	} else if (simplifiedChild->kind == eraseKind \|\|
	eraseList.count(simplifiedChild->predicate) != 0) {
	continue;
	}
	node->children.push_back(simplifiedChild);
	}
	return node;
	}

	// Combine a list of predicate expressions using a binary combiner. If a list
	// is empty, return "init".
	static std::string combineBinary(ArrayRef<std::string> children,
	std::string combiner, std::string init) {
	if (children.empty())
	return init;

	auto size = children.size();
	if (size == 1)
	return children.front();

	std::string str;
	llvm::raw_string_ostream os(str);
	os << '(' << children.front() << ')';
	for (unsigned i = 1; i < size; ++i) {
	os << ' ' << combiner << " (" << children[i] << ')';
	}
	return os.str();
	}

	// Prepend negation to the only condition in the predicate expression list.
	static std::string combineNot(ArrayRef<std::string> children) {
	assert(children.size() == 1 && "expected exactly one child predicate of Neg");
	return (Twine("!(") + children.front() + Twine(')')).str();
	}

	// Recursively traverse the predicate tree in depth-first post-order and build
	// the final expression.
	static std::string getCombinedCondition(const PredNode &root) {
	// Immediately return for non-combiner predicates that don't have children.
	if (root.kind == PredCombinerKind::Leaf)
	return root.expr;
	if (root.kind == PredCombinerKind::True)
	return "true";
	if (root.kind == PredCombinerKind::False)
	return "false";

	// Recurse into children.
	llvm::SmallVector<std::string, 4> childExpressions;
	childExpressions.reserve(root.children.size());
	for (const auto &child : root.children)
	childExpressions.push_back(getCombinedCondition(*child));

	// Combine the expressions based on the predicate node kind.
	if (root.kind == PredCombinerKind::And)
	return combineBinary(childExpressions, "&&", "true");
	if (root.kind == PredCombinerKind::Or)
	return combineBinary(childExpressions, "\|\|", "false");
	if (root.kind == PredCombinerKind::Not)
	return combineNot(childExpressions);
	if (root.kind == PredCombinerKind::Concat) {
	assert(childExpressions.size() == 1 &&
	"ConcatPred should only have one child");
	return root.prefix + childExpressions.front() + root.suffix;
	}

	// Substitutions were applied before so just ignore them.
	if (root.kind == PredCombinerKind::SubstLeaves) {
	assert(childExpressions.size() == 1 &&
	"substitution predicate must have one child");
	return childExpressions[0];
	}

	llvm::PrintFatalError(root.predicate->getLoc(), "unsupported predicate kind");
	}

	std::string CombinedPred::getConditionImpl() const {
	llvm::SpecificBumpPtrAllocator<PredNode> allocator;
	auto predicateTree = buildPredicateTree(*this, allocator, {});
	predicateTree =
	propagateGroundTruth(predicateTree,
	/knownTruePreds=/llvm::SmallPtrSet<Pred *, 2>(),
	/knownFalsePreds=/llvm::SmallPtrSet<Pred *, 2>());

	return getCombinedCondition(*predicateTree);
	}

	StringRef SubstLeavesPred::getPattern() const {
	return def->getValueAsString("pattern");
	}

	StringRef SubstLeavesPred::getReplacement() const {
	return def->getValueAsString("replacement");
	}

	StringRef ConcatPred::getPrefix() const {
	return def->getValueAsString("prefix");
	}

	StringRef ConcatPred::getSuffix() const {
	return def->getValueAsString("suffix");
	}