lib/IR/AsmPrinter.cpp - platform/external/tensorflow - Gitiles

 //===- AsmPrinter.cpp - MLIR Assembly Printer Implementation --------------===//
 //
 // Copyright 2019 The MLIR Authors.
 //
 // Licensed under the Apache License, Version 2.0 (the "License");
 // you may not use this file except in compliance with the License.
 // You may obtain a copy of the License at
 //
 //   http://www.apache.org/licenses/LICENSE-2.0
 //
 // Unless required by applicable law or agreed to in writing, software
 // distributed under the License is distributed on an "AS IS" BASIS,
 // WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
 // See the License for the specific language governing permissions and
 // limitations under the License.
 // =============================================================================
 //
 // This file implements the MLIR AsmPrinter class, which is used to implement
 // the various print() methods on the core IR objects.
 //
 //===----------------------------------------------------------------------===//

 #include "mlir/IR/AffineExpr.h"
 #include "mlir/IR/AffineMap.h"
 #include "mlir/IR/Attributes.h"
 #include "mlir/IR/CFGFunction.h"
 #include "mlir/IR/MLFunction.h"
 #include "mlir/IR/Module.h"
 #include "mlir/IR/OperationSet.h"
 #include "mlir/IR/Statements.h"
 #include "mlir/IR/Types.h"
 #include "mlir/Support/STLExtras.h"
 #include "llvm/ADT/DenseMap.h"
 #include "llvm/Support/raw_ostream.h"
 using namespace mlir;


 void Identifier::print(raw_ostream &os) const {
   os << str();
 }

 void Identifier::dump() const {
   print(llvm::errs());
 }

 //===----------------------------------------------------------------------===//
 // Module printing
 //===----------------------------------------------------------------------===//

 namespace {
 class ModuleState  {
  public:
   ModuleState(raw_ostream &os);

   void initialize(const Module *module);

   void print(const Module *module);
   void print(const Type *type) const;
   void print(const Function* fn);

   void recordAffineMapReference(const AffineMap* affineMap) {
     if (affineMapIds.count(affineMap) == 0) {
       affineMapIds[affineMap] = nextAffineMapId++;
     }
   }

   int getAffineMapId(const AffineMap* affineMap) const {
     auto it = affineMapIds.find(affineMap);
     if (it == affineMapIds.end()) {
       return -1;
     }
     return it->second;
   }

  private:
   // Visit functions.
   void visitFunction(const Function *fn);
   void visitExtFunction(const ExtFunction *fn);
   void visitCFGFunction(const CFGFunction *fn);
   void visitMLFunction(const MLFunction *fn);
   void visitType(const Type *type);

   raw_ostream &os;
   DenseMap<const AffineMap*, int> affineMapIds;
   int nextAffineMapId = 0;
 };
 } // end anonymous namespace

 ModuleState::ModuleState(raw_ostream &os) : os(os) {
 }

 // Initializes module state, populating affine map state.
 void ModuleState::initialize(const Module *module) {
   for (auto fn : module->functionList) {
     visitFunction(fn);
   }
 }

 // TODO Support visiting other types/instructions when implemented.
 void ModuleState::visitType(const Type *type) {
   if (type->getKind() == Type::Kind::Function) {
     // Visit input and result types for functions.
     auto *funcType = cast<FunctionType>(type);
     for (auto* input : funcType->getInputs()) {
       visitType(input);
     }
     for (auto* result : funcType->getResults()) {
       visitType(result);
     }
   } else if (type->getKind() == Type::Kind::MemRef) {
     // Visit affine maps in memref type.
     auto *memref = cast<MemRefType>(type);
     for (AffineMap* map : memref->getAffineMaps()) {
       recordAffineMapReference(map);
     }
   }
 }

 void ModuleState::visitExtFunction(const ExtFunction *fn) {
   visitType(fn->getType());
 }

 void ModuleState::visitCFGFunction(const CFGFunction *fn) {
   visitType(fn->getType());
   // TODO Visit function body instructions.
 }

 void ModuleState::visitMLFunction(const MLFunction *fn) {
   visitType(fn->getType());
   // TODO Visit function body statements.
 }

 void ModuleState::visitFunction(const Function *fn) {
   switch (fn->getKind()) {
     case Function::Kind::ExtFunc:
       return visitExtFunction(cast<ExtFunction>(fn));
     case Function::Kind::CFGFunc:
       return visitCFGFunction(cast<CFGFunction>(fn));
     case Function::Kind::MLFunc:
       return visitMLFunction(cast<MLFunction>(fn));
   }
 }

 static void printExtFunction(const ExtFunction* fn,
                              const ModuleState* moduleState, raw_ostream &os);


 static void printCFGFunction(const CFGFunction* fn,
                              const ModuleState* moduleState, raw_ostream &os);

 static void printMLFunction(const MLFunction* fn,
                             const ModuleState* moduleState, raw_ostream &os);

 // Prints function with initialized module state.
 void ModuleState::print(const Function* fn) {
   switch (fn->getKind()) {
     case Function::Kind::ExtFunc:
       return printExtFunction(cast<ExtFunction>(fn), this, os);
     case Function::Kind::CFGFunc:
       return printCFGFunction(cast<CFGFunction>(fn), this, os);
     case Function::Kind::MLFunc:
       return printMLFunction(cast<MLFunction>(fn), this, os);
   }
 }

 // Prints affine map identifier.
 static void printAffineMapId(unsigned affineMapId, raw_ostream &os) {
   os << "#map" << affineMapId;
 }

 void ModuleState::print(const Module *module) {
   for (const auto& mapAndId : affineMapIds) {
     printAffineMapId(mapAndId.second, os);
     os << " = ";
     mapAndId.first->print(os);
     os << '\n';
   }
   for (auto *fn : module->functionList)
     print(fn);
 }

 void ModuleState::print(const Type *type) const {
   switch (type->getKind()) {
   case Type::Kind::AffineInt: os << "affineint"; return;
   case Type::Kind::BF16: os << "bf16"; return;
   case Type::Kind::F16:  os << "f16"; return;
   case Type::Kind::F32:  os << "f32"; return;
   case Type::Kind::F64:  os << "f64"; return;

   case Type::Kind::Integer: {
     auto *integer = cast<IntegerType>(type);
     os << 'i' << integer->getWidth();
     return;
   }
   case Type::Kind::Function: {
     auto *func = cast<FunctionType>(type);
     os << '(';
     interleave(func->getInputs(),
                [&](Type *type) { os << *type; },
                [&]() { os << ", "; });
     os << ") -> ";
     auto results = func->getResults();
     if (results.size() == 1)
       os << *results[0];
     else {
       os << '(';
       interleave(results,
                  [&](Type *type) { os << *type; },
                  [&]() { os << ", "; });
       os << ')';
     }
     return;
   }
   case Type::Kind::Vector: {
     auto *v = cast<VectorType>(type);
     os << "vector<";
     for (auto dim : v->getShape())
       os << dim << 'x';
     os << *v->getElementType() << '>';
     return;
   }
   case Type::Kind::RankedTensor: {
     auto *v = cast<RankedTensorType>(type);
     os << "tensor<";
     for (auto dim : v->getShape()) {
       if (dim < 0)
         os << '?';
       else
         os << dim;
       os << 'x';
     }
     os << *v->getElementType() << '>';
     return;
   }
   case Type::Kind::UnrankedTensor: {
     auto *v = cast<UnrankedTensorType>(type);
     os << "tensor<??" << *v->getElementType() << '>';
     return;
   }
   case Type::Kind::MemRef: {
     auto *v = cast<MemRefType>(type);
     os << "memref<";
     for (auto dim : v->getShape()) {
       if (dim < 0)
         os << '?';
       else
         os << dim;
       os << 'x';
     }
     os << *v->getElementType();
     for (auto map : v->getAffineMaps()) {
       os << ", ";
       const int mapId = getAffineMapId(map);
       if (mapId >= 0) {
         // Map will be printed at top of module so print reference to its id.
         printAffineMapId(mapId, os);
       } else {
         // Map not in module state so print inline.
         map->print(os);
       }
     }
     os << ", " << v->getMemorySpace();
     os << '>';
     return;
   }
   }
 }

 //===----------------------------------------------------------------------===//
 // Function printing
 //===----------------------------------------------------------------------===//

 static void printFunctionSignature(const Function *fn,
                                    const ModuleState *moduleState,
                                    raw_ostream &os) {
   auto type = fn->getType();

   os << "@" << fn->getName() << '(';
   interleave(type->getInputs(),
              [&](Type *eltType) { moduleState->print(eltType); },
              [&]() { os << ", "; });
   os << ')';

   switch (type->getResults().size()) {
   case 0: break;
   case 1:
     os << " -> ";
     moduleState->print(type->getResults()[0]);
     break;
   default:
     os << " -> (";
     interleave(type->getResults(),
                [&](Type *eltType) { moduleState->print(eltType); },
                [&]() { os << ", "; });
     os << ')';
     break;
   }
 }

 void ExtFunction::print(raw_ostream &os) const {
   ModuleState moduleState(os);
   os << "extfunc ";
   printFunctionSignature(this, &moduleState, os);
   os << "\n";
 }

 namespace {

 // FunctionState contains common functionality for printing
 // CFG and ML functions.
 class FunctionState {
 public:
   FunctionState(MLIRContext *context, const ModuleState *moduleState,
                 raw_ostream &os);

   void printOperation(const Operation *op);

 protected:
   raw_ostream &os;
   const ModuleState *moduleState;
   const OperationSet &operationSet;
 };
 } // end anonymous namespace

 FunctionState::FunctionState(MLIRContext *context,
                              const ModuleState *moduleState,
                              raw_ostream &os)
     : os(os), moduleState(moduleState),
       operationSet(OperationSet::get(context)) {}

 void FunctionState::printOperation(const Operation *op) {
   // Check to see if this is a known operation.  If so, use the registered
   // custom printer hook.
   if (auto opInfo = operationSet.lookup(op->getName().str())) {
     os << "  ";
     opInfo->printAssembly(op, os);
     return;
   }

   // TODO: escape name if necessary.
   os << "  \"" << op->getName().str() << "\"()";

   auto attrs = op->getAttrs();
   if (!attrs.empty()) {
     os << '{';
     interleave(
         attrs,
         [&](NamedAttribute attr) { os << attr.first << ": " << *attr.second; },
         [&]() { os << ", "; });
     os << '}';
   }
 }

 //===----------------------------------------------------------------------===//
 // CFG Function printing
 //===----------------------------------------------------------------------===//

 namespace {
 class CFGFunctionState : public FunctionState {
 public:
   CFGFunctionState(const CFGFunction *function, const ModuleState *moduleState,
                    raw_ostream &os);

   const CFGFunction *getFunction() const { return function; }

   void print();
   void print(const BasicBlock *block);

   void print(const Instruction *inst);
   void print(const OperationInst *inst);
   void print(const ReturnInst *inst);
   void print(const BranchInst *inst);

   unsigned getBBID(const BasicBlock *block) {
     auto it = basicBlockIDs.find(block);
     assert(it != basicBlockIDs.end() && "Block not in this function?");
     return it->second;
   }

 private:
   const CFGFunction *function;
   DenseMap<const BasicBlock*, unsigned> basicBlockIDs;
 };
 } // end anonymous namespace

 CFGFunctionState::CFGFunctionState(const CFGFunction *function,
                                    const ModuleState *moduleState,
                                    raw_ostream &os)
     : FunctionState(function->getContext(), moduleState, os),
       function(function) {
   // Each basic block gets a unique ID per function.
   unsigned blockID = 0;
   for (auto &block : *function)
     basicBlockIDs[&block] = blockID++;
 }

 void CFGFunctionState::print() {
   os << "cfgfunc ";
   printFunctionSignature(this->getFunction(), moduleState, os);
   os << " {\n";

   for (auto &block : *function)
     print(&block);
   os << "}\n\n";
 }

 void CFGFunctionState::print(const BasicBlock *block) {
   os << "bb" << getBBID(block) << ":\n";

   // TODO Print arguments.
   for (auto &inst : block->getOperations()) {
     print(&inst);
     os << "\n";
   }

   print(block->getTerminator());
   os << "\n";
 }

 void CFGFunctionState::print(const Instruction *inst) {
   switch (inst->getKind()) {
   case Instruction::Kind::Operation:
     return print(cast<OperationInst>(inst));
   case TerminatorInst::Kind::Branch:
     return print(cast<BranchInst>(inst));
   case TerminatorInst::Kind::Return:
     return print(cast<ReturnInst>(inst));
   }
 }

 void CFGFunctionState::print(const OperationInst *inst) {
   printOperation(inst);
 }

 void CFGFunctionState::print(const BranchInst *inst) {
   os << "  br bb" << getBBID(inst->getDest());
 }
 void CFGFunctionState::print(const ReturnInst *inst) {
   os << "  return";
 }

 //===----------------------------------------------------------------------===//
 // ML Function printing
 //===----------------------------------------------------------------------===//

 namespace {
 class MLFunctionState : public FunctionState {
 public:
   MLFunctionState(const MLFunction *function, const ModuleState *moduleState,
                   raw_ostream &os);

   const MLFunction *getFunction() const { return function; }

   // Prints ML function
   void print();

   // Methods to print ML function statements
   void print(const Statement *stmt);
   void print(const OperationStmt *stmt);
   void print(const ForStmt *stmt);
   void print(const IfStmt *stmt);
   void print(const StmtBlock *block);

   // Number of spaces used for indenting nested statements
   const static unsigned indentWidth = 2;

 private:
   const MLFunction *function;
   int numSpaces;
 };
 } // end anonymous namespace

 MLFunctionState::MLFunctionState(const MLFunction *function,
                                  const ModuleState *moduleState,
                                  raw_ostream &os)
     : FunctionState(function->getContext(), moduleState, os),
       function(function), numSpaces(0) {}

 void MLFunctionState::print() {
   os << "mlfunc ";
   // FIXME: should print argument names rather than just signature
   printFunctionSignature(function, moduleState, os);
   os << " {\n";
   print(function);
   os << "  return\n";
   os << "}\n\n";
 }

 void MLFunctionState::print(const StmtBlock *block) {
   numSpaces += indentWidth;
   for (auto &stmt : block->getStatements()) {
     print(&stmt);
     os << "\n";
   }
   numSpaces -= indentWidth;
 }

 void MLFunctionState::print(const Statement *stmt) {
   switch (stmt->getKind()) {
   case Statement::Kind::Operation:
     return print(cast<OperationStmt>(stmt));
   case Statement::Kind::For:
     return print(cast<ForStmt>(stmt));
   case Statement::Kind::If:
     return print(cast<IfStmt>(stmt));
   }
 }

 void MLFunctionState::print(const OperationStmt *stmt) {
   printOperation(stmt);
 }

 void MLFunctionState::print(const ForStmt *stmt) {
   os.indent(numSpaces) << "for {\n";
   print(static_cast<const StmtBlock *>(stmt));
   os.indent(numSpaces) << "}";
 }

 void MLFunctionState::print(const IfStmt *stmt) {
   os.indent(numSpaces) << "if () {\n";
   print(stmt->getThenClause());
   os.indent(numSpaces) << "}";
   if (stmt->hasElseClause()) {
     os << " else {\n";
     print(stmt->getElseClause());
     os.indent(numSpaces) << "}";
   }
 }

 void printExtFunction(const ExtFunction* fn, const ModuleState* moduleState,
                       raw_ostream &os) {
   os << "extfunc ";
   printFunctionSignature(fn, moduleState, os);
   os << '\n';
 }

 void printCFGFunction(const CFGFunction* fn, const ModuleState* moduleState,
                       raw_ostream &os) {
   CFGFunctionState state(fn, moduleState, os);
   state.print();
 }

 void printMLFunction(const MLFunction* fn, const ModuleState* moduleState,
                      raw_ostream &os) {
   MLFunctionState state(fn, moduleState, os);
   state.print();
 }

 //===----------------------------------------------------------------------===//
 // print and dump methods
 //===----------------------------------------------------------------------===//

 void Type::print(raw_ostream &os) const {
   ModuleState moduleState(os);
   moduleState.print(this);
 }

 void Type::dump() const {
   print(llvm::errs());
 }

 void Instruction::print(raw_ostream &os) const {
   ModuleState moduleState(os);
   CFGFunctionState state(getFunction(), &moduleState, os);
   state.print(this);
 }

 void Instruction::dump() const {
   print(llvm::errs());
   llvm::errs() << "\n";
 }

 void AffineMap::dump() const {
   print(llvm::errs());
   llvm::errs() << "\n";
 }

 void AffineExpr::dump() const {
   print(llvm::errs());
   llvm::errs() << "\n";
 }

 void AffineAddExpr::print(raw_ostream &os) const {
   os << "(" << *getLHS() << " + " << *getRHS() << ")";
 }

 void AffineSubExpr::print(raw_ostream &os) const {
   os << "(" << *getLHS() << " - " << *getRHS() << ")";
 }

 void AffineMulExpr::print(raw_ostream &os) const {
   os << "(" << *getLHS() << " * " << *getRHS() << ")";
 }

 void AffineModExpr::print(raw_ostream &os) const {
   os << "(" << *getLHS() << " mod " << *getRHS() << ")";
 }

 void AffineFloorDivExpr::print(raw_ostream &os) const {
   os << "(" << *getLHS() << " floordiv " << *getRHS() << ")";
 }

 void AffineCeilDivExpr::print(raw_ostream &os) const {
   os << "(" << *getLHS() << " ceildiv " << *getRHS() << ")";
 }

 void AffineSymbolExpr::print(raw_ostream &os) const {
   os << "s" << getPosition();
 }

 void AffineDimExpr::print(raw_ostream &os) const { os << "d" << getPosition(); }

 void AffineConstantExpr::print(raw_ostream &os) const { os << getValue(); }

 void AffineExpr::print(raw_ostream &os) const {
   switch (getKind()) {
   case Kind::SymbolId:
     return cast<AffineSymbolExpr>(this)->print(os);
   case Kind::DimId:
     return cast<AffineDimExpr>(this)->print(os);
   case Kind::Constant:
     return cast<AffineConstantExpr>(this)->print(os);
   case Kind::Add:
     return cast<AffineAddExpr>(this)->print(os);
   case Kind::Sub:
     return cast<AffineSubExpr>(this)->print(os);
   case Kind::Mul:
     return cast<AffineMulExpr>(this)->print(os);
   case Kind::FloorDiv:
     return cast<AffineFloorDivExpr>(this)->print(os);
   case Kind::CeilDiv:
     return cast<AffineCeilDivExpr>(this)->print(os);
   case Kind::Mod:
     return cast<AffineModExpr>(this)->print(os);
   }
 }

 void AffineMap::print(raw_ostream &os) const {
   // Dimension identifiers.
   os << "(";
   for (int i = 0; i < (int)getNumDims() - 1; i++)
     os << "d" << i << ", ";
   if (getNumDims() >= 1)
     os << "d" << getNumDims() - 1;
   os << ")";

   // Symbolic identifiers.
   if (getNumSymbols() >= 1) {
     os << " [";
     for (int i = 0; i < (int)getNumSymbols() - 1; i++)
       os << "s" << i << ", ";
     if (getNumSymbols() >= 1)
       os << "s" << getNumSymbols() - 1;
     os << "]";
   }

   // AffineMap should have at least one result.
   assert(!getResults().empty());
   // Result affine expressions.
   os << " -> (";
   interleave(getResults(), [&](AffineExpr *expr) { os << *expr; },
              [&]() { os << ", "; });
   os << ")";

   if (!isBounded()) {
     return;
   }

   // Print range sizes for bounded affine maps.
   os << " size (";
   interleave(getRangeSizes(), [&](AffineExpr *expr) { os << *expr; },
              [&]() { os << ", "; });
   os << ")";
 }

 void BasicBlock::print(raw_ostream &os) const {
   ModuleState moduleState(os);
   CFGFunctionState state(getFunction(), &moduleState, os);
   state.print();
 }

 void BasicBlock::dump() const {
   print(llvm::errs());
 }

 void Statement::print(raw_ostream &os) const {
   ModuleState moduleState(os);
   MLFunctionState state(getFunction(), &moduleState, os);
   state.print(this);
 }

 void Statement::dump() const {
   print(llvm::errs());
 }

 void Function::print(raw_ostream &os) const {
   switch (getKind()) {
   case Kind::ExtFunc: return cast<ExtFunction>(this)->print(os);
   case Kind::CFGFunc: return cast<CFGFunction>(this)->print(os);
   case Kind::MLFunc:  return cast<MLFunction>(this)->print(os);
   }
 }

 void Function::dump() const {
   print(llvm::errs());
 }

 void CFGFunction::print(raw_ostream &os) const {
   ModuleState moduleState(os);
   CFGFunctionState state(this, &moduleState, os);
   state.print();
 }

 void MLFunction::print(raw_ostream &os) const {
   ModuleState moduleState(os);
   MLFunctionState state(this, &moduleState, os);
   state.print();
 }

 void Module::print(raw_ostream &os) const {
   ModuleState moduleState(os);
   moduleState.initialize(this);
   moduleState.print(this);
 }

 void Module::dump() const {
   print(llvm::errs());
 }
	//===- AsmPrinter.cpp - MLIR Assembly Printer Implementation --------------===//
	//
	// Copyright 2019 The MLIR Authors.
	//
	// Licensed under the Apache License, Version 2.0 (the "License");
	// you may not use this file except in compliance with the License.
	// You may obtain a copy of the License at
	//
	// http://www.apache.org/licenses/LICENSE-2.0
	//
	// Unless required by applicable law or agreed to in writing, software
	// distributed under the License is distributed on an "AS IS" BASIS,
	// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
	// See the License for the specific language governing permissions and
	// limitations under the License.
	// =============================================================================
	//
	// This file implements the MLIR AsmPrinter class, which is used to implement
	// the various print() methods on the core IR objects.
	//
	//===----------------------------------------------------------------------===//

	#include "mlir/IR/AffineExpr.h"
	#include "mlir/IR/AffineMap.h"
	#include "mlir/IR/Attributes.h"
	#include "mlir/IR/CFGFunction.h"
	#include "mlir/IR/MLFunction.h"
	#include "mlir/IR/Module.h"
	#include "mlir/IR/OperationSet.h"
	#include "mlir/IR/Statements.h"
	#include "mlir/IR/Types.h"
	#include "mlir/Support/STLExtras.h"
	#include "llvm/ADT/DenseMap.h"
	#include "llvm/Support/raw_ostream.h"
	using namespace mlir;


	void Identifier::print(raw_ostream &os) const {
	os << str();
	}

	void Identifier::dump() const {
	print(llvm::errs());
	}

	//===----------------------------------------------------------------------===//
	// Module printing
	//===----------------------------------------------------------------------===//

	namespace {
	class ModuleState {
	public:
	ModuleState(raw_ostream &os);

	void initialize(const Module *module);

	void print(const Module *module);
	void print(const Type *type) const;
	void print(const Function* fn);

	void recordAffineMapReference(const AffineMap* affineMap) {
	if (affineMapIds.count(affineMap) == 0) {
	affineMapIds[affineMap] = nextAffineMapId++;
	}
	}

	int getAffineMapId(const AffineMap* affineMap) const {
	auto it = affineMapIds.find(affineMap);
	if (it == affineMapIds.end()) {
	return -1;
	}
	return it->second;
	}

	private:
	// Visit functions.
	void visitFunction(const Function *fn);
	void visitExtFunction(const ExtFunction *fn);
	void visitCFGFunction(const CFGFunction *fn);
	void visitMLFunction(const MLFunction *fn);
	void visitType(const Type *type);

	raw_ostream &os;
	DenseMap<const AffineMap*, int> affineMapIds;
	int nextAffineMapId = 0;
	};
	} // end anonymous namespace

	ModuleState::ModuleState(raw_ostream &os) : os(os) {
	}

	// Initializes module state, populating affine map state.
	void ModuleState::initialize(const Module *module) {
	for (auto fn : module->functionList) {
	visitFunction(fn);
	}
	}

	// TODO Support visiting other types/instructions when implemented.
	void ModuleState::visitType(const Type *type) {
	if (type->getKind() == Type::Kind::Function) {
	// Visit input and result types for functions.
	auto *funcType = cast<FunctionType>(type);
	for (auto* input : funcType->getInputs()) {
	visitType(input);
	}
	for (auto* result : funcType->getResults()) {
	visitType(result);
	}
	} else if (type->getKind() == Type::Kind::MemRef) {
	// Visit affine maps in memref type.
	auto *memref = cast<MemRefType>(type);
	for (AffineMap* map : memref->getAffineMaps()) {
	recordAffineMapReference(map);
	}
	}
	}

	void ModuleState::visitExtFunction(const ExtFunction *fn) {
	visitType(fn->getType());
	}

	void ModuleState::visitCFGFunction(const CFGFunction *fn) {
	visitType(fn->getType());
	// TODO Visit function body instructions.
	}

	void ModuleState::visitMLFunction(const MLFunction *fn) {
	visitType(fn->getType());
	// TODO Visit function body statements.
	}

	void ModuleState::visitFunction(const Function *fn) {
	switch (fn->getKind()) {
	case Function::Kind::ExtFunc:
	return visitExtFunction(cast<ExtFunction>(fn));
	case Function::Kind::CFGFunc:
	return visitCFGFunction(cast<CFGFunction>(fn));
	case Function::Kind::MLFunc:
	return visitMLFunction(cast<MLFunction>(fn));
	}
	}

	static void printExtFunction(const ExtFunction* fn,
	const ModuleState* moduleState, raw_ostream &os);


	static void printCFGFunction(const CFGFunction* fn,
	const ModuleState* moduleState, raw_ostream &os);

	static void printMLFunction(const MLFunction* fn,
	const ModuleState* moduleState, raw_ostream &os);

	// Prints function with initialized module state.
	void ModuleState::print(const Function* fn) {
	switch (fn->getKind()) {
	case Function::Kind::ExtFunc:
	return printExtFunction(cast<ExtFunction>(fn), this, os);
	case Function::Kind::CFGFunc:
	return printCFGFunction(cast<CFGFunction>(fn), this, os);
	case Function::Kind::MLFunc:
	return printMLFunction(cast<MLFunction>(fn), this, os);
	}
	}

	// Prints affine map identifier.
	static void printAffineMapId(unsigned affineMapId, raw_ostream &os) {
	os << "#map" << affineMapId;
	}

	void ModuleState::print(const Module *module) {
	for (const auto& mapAndId : affineMapIds) {
	printAffineMapId(mapAndId.second, os);
	os << " = ";
	mapAndId.first->print(os);
	os << '\n';
	}
	for (auto *fn : module->functionList)
	print(fn);
	}

	void ModuleState::print(const Type *type) const {
	switch (type->getKind()) {
	case Type::Kind::AffineInt: os << "affineint"; return;
	case Type::Kind::BF16: os << "bf16"; return;
	case Type::Kind::F16: os << "f16"; return;
	case Type::Kind::F32: os << "f32"; return;
	case Type::Kind::F64: os << "f64"; return;

	case Type::Kind::Integer: {
	auto *integer = cast<IntegerType>(type);
	os << 'i' << integer->getWidth();
	return;
	}
	case Type::Kind::Function: {
	auto *func = cast<FunctionType>(type);
	os << '(';
	interleave(func->getInputs(),
	[&](Type type) { os << type; },
	[&]() { os << ", "; });
	os << ") -> ";
	auto results = func->getResults();
	if (results.size() == 1)
	os << *results[0];
	else {
	os << '(';
	interleave(results,
	[&](Type type) { os << type; },
	[&]() { os << ", "; });
	os << ')';
	}
	return;
	}
	case Type::Kind::Vector: {
	auto *v = cast<VectorType>(type);
	os << "vector<";
	for (auto dim : v->getShape())
	os << dim << 'x';
	os << *v->getElementType() << '>';
	return;
	}
	case Type::Kind::RankedTensor: {
	auto *v = cast<RankedTensorType>(type);
	os << "tensor<";
	for (auto dim : v->getShape()) {
	if (dim < 0)
	os << '?';
	else
	os << dim;
	os << 'x';
	}
	os << *v->getElementType() << '>';
	return;
	}
	case Type::Kind::UnrankedTensor: {
	auto *v = cast<UnrankedTensorType>(type);
	os << "tensor<??" << *v->getElementType() << '>';
	return;
	}
	case Type::Kind::MemRef: {
	auto *v = cast<MemRefType>(type);
	os << "memref<";
	for (auto dim : v->getShape()) {
	if (dim < 0)
	os << '?';
	else
	os << dim;
	os << 'x';
	}
	os << *v->getElementType();
	for (auto map : v->getAffineMaps()) {
	os << ", ";
	const int mapId = getAffineMapId(map);
	if (mapId >= 0) {
	// Map will be printed at top of module so print reference to its id.
	printAffineMapId(mapId, os);
	} else {
	// Map not in module state so print inline.
	map->print(os);
	}
	}
	os << ", " << v->getMemorySpace();
	os << '>';
	return;
	}
	}
	}

	//===----------------------------------------------------------------------===//
	// Function printing
	//===----------------------------------------------------------------------===//

	static void printFunctionSignature(const Function *fn,
	const ModuleState *moduleState,
	raw_ostream &os) {
	auto type = fn->getType();

	os << "@" << fn->getName() << '(';
	interleave(type->getInputs(),
	[&](Type *eltType) { moduleState->print(eltType); },
	[&]() { os << ", "; });
	os << ')';

	switch (type->getResults().size()) {
	case 0: break;
	case 1:
	os << " -> ";
	moduleState->print(type->getResults()[0]);
	break;
	default:
	os << " -> (";
	interleave(type->getResults(),
	[&](Type *eltType) { moduleState->print(eltType); },
	[&]() { os << ", "; });
	os << ')';
	break;
	}
	}

	void ExtFunction::print(raw_ostream &os) const {
	ModuleState moduleState(os);
	os << "extfunc ";
	printFunctionSignature(this, &moduleState, os);
	os << "\n";
	}

	namespace {

	// FunctionState contains common functionality for printing
	// CFG and ML functions.
	class FunctionState {
	public:
	FunctionState(MLIRContext context, const ModuleState moduleState,
	raw_ostream &os);

	void printOperation(const Operation *op);

	protected:
	raw_ostream &os;
	const ModuleState *moduleState;
	const OperationSet &operationSet;
	};
	} // end anonymous namespace

	FunctionState::FunctionState(MLIRContext *context,
	const ModuleState *moduleState,
	raw_ostream &os)
	: os(os), moduleState(moduleState),
	operationSet(OperationSet::get(context)) {}

	void FunctionState::printOperation(const Operation *op) {
	// Check to see if this is a known operation. If so, use the registered
	// custom printer hook.
	if (auto opInfo = operationSet.lookup(op->getName().str())) {
	os << " ";
	opInfo->printAssembly(op, os);
	return;
	}

	// TODO: escape name if necessary.
	os << " \"" << op->getName().str() << "\"()";

	auto attrs = op->getAttrs();
	if (!attrs.empty()) {
	os << '{';
	interleave(
	attrs,
	[&](NamedAttribute attr) { os << attr.first << ": " << *attr.second; },
	[&]() { os << ", "; });
	os << '}';
	}
	}

	//===----------------------------------------------------------------------===//
	// CFG Function printing
	//===----------------------------------------------------------------------===//

	namespace {
	class CFGFunctionState : public FunctionState {
	public:
	CFGFunctionState(const CFGFunction function, const ModuleState moduleState,
	raw_ostream &os);

	const CFGFunction *getFunction() const { return function; }

	void print();
	void print(const BasicBlock *block);

	void print(const Instruction *inst);
	void print(const OperationInst *inst);
	void print(const ReturnInst *inst);
	void print(const BranchInst *inst);

	unsigned getBBID(const BasicBlock *block) {
	auto it = basicBlockIDs.find(block);
	assert(it != basicBlockIDs.end() && "Block not in this function?");
	return it->second;
	}

	private:
	const CFGFunction *function;
	DenseMap<const BasicBlock*, unsigned> basicBlockIDs;
	};
	} // end anonymous namespace

	CFGFunctionState::CFGFunctionState(const CFGFunction *function,
	const ModuleState *moduleState,
	raw_ostream &os)
	: FunctionState(function->getContext(), moduleState, os),
	function(function) {
	// Each basic block gets a unique ID per function.
	unsigned blockID = 0;
	for (auto &block : *function)
	basicBlockIDs[&block] = blockID++;
	}

	void CFGFunctionState::print() {
	os << "cfgfunc ";
	printFunctionSignature(this->getFunction(), moduleState, os);
	os << " {\n";

	for (auto &block : *function)
	print(&block);
	os << "}\n\n";
	}

	void CFGFunctionState::print(const BasicBlock *block) {
	os << "bb" << getBBID(block) << ":\n";

	// TODO Print arguments.
	for (auto &inst : block->getOperations()) {
	print(&inst);
	os << "\n";
	}

	print(block->getTerminator());
	os << "\n";
	}

	void CFGFunctionState::print(const Instruction *inst) {
	switch (inst->getKind()) {
	case Instruction::Kind::Operation:
	return print(cast<OperationInst>(inst));
	case TerminatorInst::Kind::Branch:
	return print(cast<BranchInst>(inst));
	case TerminatorInst::Kind::Return:
	return print(cast<ReturnInst>(inst));
	}
	}

	void CFGFunctionState::print(const OperationInst *inst) {
	printOperation(inst);
	}

	void CFGFunctionState::print(const BranchInst *inst) {
	os << " br bb" << getBBID(inst->getDest());
	}
	void CFGFunctionState::print(const ReturnInst *inst) {
	os << " return";
	}

	//===----------------------------------------------------------------------===//
	// ML Function printing
	//===----------------------------------------------------------------------===//

	namespace {
	class MLFunctionState : public FunctionState {
	public:
	MLFunctionState(const MLFunction function, const ModuleState moduleState,
	raw_ostream &os);

	const MLFunction *getFunction() const { return function; }

	// Prints ML function
	void print();

	// Methods to print ML function statements
	void print(const Statement *stmt);
	void print(const OperationStmt *stmt);
	void print(const ForStmt *stmt);
	void print(const IfStmt *stmt);
	void print(const StmtBlock *block);

	// Number of spaces used for indenting nested statements
	const static unsigned indentWidth = 2;

	private:
	const MLFunction *function;
	int numSpaces;
	};
	} // end anonymous namespace

	MLFunctionState::MLFunctionState(const MLFunction *function,
	const ModuleState *moduleState,
	raw_ostream &os)
	: FunctionState(function->getContext(), moduleState, os),
	function(function), numSpaces(0) {}

	void MLFunctionState::print() {
	os << "mlfunc ";
	// FIXME: should print argument names rather than just signature
	printFunctionSignature(function, moduleState, os);
	os << " {\n";
	print(function);
	os << " return\n";
	os << "}\n\n";
	}

	void MLFunctionState::print(const StmtBlock *block) {
	numSpaces += indentWidth;
	for (auto &stmt : block->getStatements()) {
	print(&stmt);
	os << "\n";
	}
	numSpaces -= indentWidth;
	}

	void MLFunctionState::print(const Statement *stmt) {
	switch (stmt->getKind()) {
	case Statement::Kind::Operation:
	return print(cast<OperationStmt>(stmt));
	case Statement::Kind::For:
	return print(cast<ForStmt>(stmt));
	case Statement::Kind::If:
	return print(cast<IfStmt>(stmt));
	}
	}

	void MLFunctionState::print(const OperationStmt *stmt) {
	printOperation(stmt);
	}

	void MLFunctionState::print(const ForStmt *stmt) {
	os.indent(numSpaces) << "for {\n";
	print(static_cast<const StmtBlock *>(stmt));
	os.indent(numSpaces) << "}";
	}

	void MLFunctionState::print(const IfStmt *stmt) {
	os.indent(numSpaces) << "if () {\n";
	print(stmt->getThenClause());
	os.indent(numSpaces) << "}";
	if (stmt->hasElseClause()) {
	os << " else {\n";
	print(stmt->getElseClause());
	os.indent(numSpaces) << "}";
	}
	}

	void printExtFunction(const ExtFunction* fn, const ModuleState* moduleState,
	raw_ostream &os) {
	os << "extfunc ";
	printFunctionSignature(fn, moduleState, os);
	os << '\n';
	}

	void printCFGFunction(const CFGFunction* fn, const ModuleState* moduleState,
	raw_ostream &os) {
	CFGFunctionState state(fn, moduleState, os);
	state.print();
	}

	void printMLFunction(const MLFunction* fn, const ModuleState* moduleState,
	raw_ostream &os) {
	MLFunctionState state(fn, moduleState, os);
	state.print();
	}

	//===----------------------------------------------------------------------===//
	// print and dump methods
	//===----------------------------------------------------------------------===//

	void Type::print(raw_ostream &os) const {
	ModuleState moduleState(os);
	moduleState.print(this);
	}

	void Type::dump() const {
	print(llvm::errs());
	}

	void Instruction::print(raw_ostream &os) const {
	ModuleState moduleState(os);
	CFGFunctionState state(getFunction(), &moduleState, os);
	state.print(this);
	}

	void Instruction::dump() const {
	print(llvm::errs());
	llvm::errs() << "\n";
	}

	void AffineMap::dump() const {
	print(llvm::errs());
	llvm::errs() << "\n";
	}

	void AffineExpr::dump() const {
	print(llvm::errs());
	llvm::errs() << "\n";
	}

	void AffineAddExpr::print(raw_ostream &os) const {
	os << "(" << getLHS() << " + " << getRHS() << ")";
	}

	void AffineSubExpr::print(raw_ostream &os) const {
	os << "(" << getLHS() << " - " << getRHS() << ")";
	}

	void AffineMulExpr::print(raw_ostream &os) const {
	os << "(" << getLHS() << " " << *getRHS() << ")";
	}

	void AffineModExpr::print(raw_ostream &os) const {
	os << "(" << getLHS() << " mod " << getRHS() << ")";
	}

	void AffineFloorDivExpr::print(raw_ostream &os) const {
	os << "(" << getLHS() << " floordiv " << getRHS() << ")";
	}

	void AffineCeilDivExpr::print(raw_ostream &os) const {
	os << "(" << getLHS() << " ceildiv " << getRHS() << ")";
	}

	void AffineSymbolExpr::print(raw_ostream &os) const {
	os << "s" << getPosition();
	}

	void AffineDimExpr::print(raw_ostream &os) const { os << "d" << getPosition(); }

	void AffineConstantExpr::print(raw_ostream &os) const { os << getValue(); }

	void AffineExpr::print(raw_ostream &os) const {
	switch (getKind()) {
	case Kind::SymbolId:
	return cast<AffineSymbolExpr>(this)->print(os);
	case Kind::DimId:
	return cast<AffineDimExpr>(this)->print(os);
	case Kind::Constant:
	return cast<AffineConstantExpr>(this)->print(os);
	case Kind::Add:
	return cast<AffineAddExpr>(this)->print(os);
	case Kind::Sub:
	return cast<AffineSubExpr>(this)->print(os);
	case Kind::Mul:
	return cast<AffineMulExpr>(this)->print(os);
	case Kind::FloorDiv:
	return cast<AffineFloorDivExpr>(this)->print(os);
	case Kind::CeilDiv:
	return cast<AffineCeilDivExpr>(this)->print(os);
	case Kind::Mod:
	return cast<AffineModExpr>(this)->print(os);
	}
	}

	void AffineMap::print(raw_ostream &os) const {
	// Dimension identifiers.
	os << "(";
	for (int i = 0; i < (int)getNumDims() - 1; i++)
	os << "d" << i << ", ";
	if (getNumDims() >= 1)
	os << "d" << getNumDims() - 1;
	os << ")";

	// Symbolic identifiers.
	if (getNumSymbols() >= 1) {
	os << " [";
	for (int i = 0; i < (int)getNumSymbols() - 1; i++)
	os << "s" << i << ", ";
	if (getNumSymbols() >= 1)
	os << "s" << getNumSymbols() - 1;
	os << "]";
	}

	// AffineMap should have at least one result.
	assert(!getResults().empty());
	// Result affine expressions.
	os << " -> (";
	interleave(getResults(), [&](AffineExpr expr) { os << expr; },
	[&]() { os << ", "; });
	os << ")";

	if (!isBounded()) {
	return;
	}

	// Print range sizes for bounded affine maps.
	os << " size (";
	interleave(getRangeSizes(), [&](AffineExpr expr) { os << expr; },
	[&]() { os << ", "; });
	os << ")";
	}

	void BasicBlock::print(raw_ostream &os) const {
	ModuleState moduleState(os);
	CFGFunctionState state(getFunction(), &moduleState, os);
	state.print();
	}

	void BasicBlock::dump() const {
	print(llvm::errs());
	}

	void Statement::print(raw_ostream &os) const {
	ModuleState moduleState(os);
	MLFunctionState state(getFunction(), &moduleState, os);
	state.print(this);
	}

	void Statement::dump() const {
	print(llvm::errs());
	}

	void Function::print(raw_ostream &os) const {
	switch (getKind()) {
	case Kind::ExtFunc: return cast<ExtFunction>(this)->print(os);
	case Kind::CFGFunc: return cast<CFGFunction>(this)->print(os);
	case Kind::MLFunc: return cast<MLFunction>(this)->print(os);
	}
	}

	void Function::dump() const {
	print(llvm::errs());
	}

	void CFGFunction::print(raw_ostream &os) const {
	ModuleState moduleState(os);
	CFGFunctionState state(this, &moduleState, os);
	state.print();
	}

	void MLFunction::print(raw_ostream &os) const {
	ModuleState moduleState(os);
	MLFunctionState state(this, &moduleState, os);
	state.print();
	}

	void Module::print(raw_ostream &os) const {
	ModuleState moduleState(os);
	moduleState.initialize(this);
	moduleState.print(this);
	}

	void Module::dump() const {
	print(llvm::errs());
	}