mlir/lib/Rewrite/ByteCode.h - llvm-project - Git at Google

 //===- ByteCode.h - Pattern byte-code interpreter ---------------*- 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
 //
 //===----------------------------------------------------------------------===//
 //
 // This file declares a byte-code and interpreter for pattern rewrites in MLIR.
 // The byte-code is constructed from the PDL Interpreter dialect.
 //
 //===----------------------------------------------------------------------===//

 #ifndef MLIR_REWRITE_BYTECODE_H_
 #define MLIR_REWRITE_BYTECODE_H_

 #include "mlir/IR/PatternMatch.h"

 namespace mlir {
 namespace pdl_interp {
 class RecordMatchOp;
 } // end namespace pdl_interp

 namespace detail {
 class PDLByteCode;

 /// Use generic bytecode types. ByteCodeField refers to the actual bytecode
 /// entries. ByteCodeAddr refers to size of indices into the bytecode.
 using ByteCodeField = uint16_t;
 using ByteCodeAddr = uint32_t;
 using OwningOpRange = llvm::OwningArrayRef<Operation *>;

 //===----------------------------------------------------------------------===//
 // PDLByteCodePattern
 //===----------------------------------------------------------------------===//

 /// All of the data pertaining to a specific pattern within the bytecode.
 class PDLByteCodePattern : public Pattern {
 public:
   static PDLByteCodePattern create(pdl_interp::RecordMatchOp matchOp,
                                    ByteCodeAddr rewriterAddr);

   /// Return the bytecode address of the rewriter for this pattern.
   ByteCodeAddr getRewriterAddr() const { return rewriterAddr; }

 private:
   template <typename... Args>
   PDLByteCodePattern(ByteCodeAddr rewriterAddr, Args &&...patternArgs)
       : Pattern(std::forward<Args>(patternArgs)...),
         rewriterAddr(rewriterAddr) {}

   /// The address of the rewriter for this pattern.
   ByteCodeAddr rewriterAddr;
 };

 //===----------------------------------------------------------------------===//
 // PDLByteCodeMutableState
 //===----------------------------------------------------------------------===//

 /// This class contains the mutable state of a bytecode instance. This allows
 /// for a bytecode instance to be cached and reused across various different
 /// threads/drivers.
 class PDLByteCodeMutableState {
 public:
   /// Set the new benefit for a bytecode pattern. The `patternIndex` corresponds
   /// to the position of the pattern within the range returned by
   /// `PDLByteCode::getPatterns`.
   void updatePatternBenefit(unsigned patternIndex, PatternBenefit benefit);

   /// Cleanup any allocated state after a match/rewrite has been completed. This
   /// method should be called irregardless of whether the match+rewrite was a
   /// success or not.
   void cleanupAfterMatchAndRewrite();

 private:
   /// Allow access to data fields.
   friend class PDLByteCode;

   /// The mutable block of memory used during the matching and rewriting phases
   /// of the bytecode.
   std::vector<const void *> memory;

   /// A mutable block of memory used during the matching and rewriting phase of
   /// the bytecode to store ranges of operations. These are always stored by
   /// owning references, because at no point in the execution of the byte code
   /// we get an indexed range (view) of operations.
   std::vector<OwningOpRange> opRangeMemory;

   /// A mutable block of memory used during the matching and rewriting phase of
   /// the bytecode to store ranges of types.
   std::vector<TypeRange> typeRangeMemory;
   /// A set of type ranges that have been allocated by the byte code interpreter
   /// to provide a guaranteed lifetime.
   std::vector<llvm::OwningArrayRef<Type>> allocatedTypeRangeMemory;

   /// A mutable block of memory used during the matching and rewriting phase of
   /// the bytecode to store ranges of values.
   std::vector<ValueRange> valueRangeMemory;
   /// A set of value ranges that have been allocated by the byte code
   /// interpreter to provide a guaranteed lifetime.
   std::vector<llvm::OwningArrayRef<Value>> allocatedValueRangeMemory;

   /// The current index of ranges being iterated over for each level of nesting.
   /// These are always maintained at 0 for the loops that are not active, so we
   /// do not need to have a separate initialization phase for each loop.
   std::vector<unsigned> loopIndex;

   /// The up-to-date benefits of the patterns held by the bytecode. The order
   /// of this array corresponds 1-1 with the array of patterns in `PDLByteCode`.
   std::vector<PatternBenefit> currentPatternBenefits;
 };

 //===----------------------------------------------------------------------===//
 // PDLByteCode
 //===----------------------------------------------------------------------===//

 /// The bytecode class is also the interpreter. Contains the bytecode itself,
 /// the static info, addresses of the rewriter functions, the interpreter
 /// memory buffer, and the execution context.
 class PDLByteCode {
 public:
   /// Each successful match returns a MatchResult, which contains information
   /// necessary to execute the rewriter and indicates the originating pattern.
   struct MatchResult {
     MatchResult(Location loc, const PDLByteCodePattern &pattern,
                 PatternBenefit benefit)
         : location(loc), pattern(&pattern), benefit(benefit) {}
     MatchResult(const MatchResult &) = delete;
     MatchResult &operator=(const MatchResult &) = delete;
     MatchResult(MatchResult &&other) = default;
     MatchResult &operator=(MatchResult &&) = default;

     /// The location of operations to be replaced.
     Location location;
     /// Memory values defined in the matcher that are passed to the rewriter.
     SmallVector<const void *> values;
     /// Memory used for the range input values.
     SmallVector<TypeRange, 0> typeRangeValues;
     SmallVector<ValueRange, 0> valueRangeValues;

     /// The originating pattern that was matched. This is always non-null, but
     /// represented with a pointer to allow for assignment.
     const PDLByteCodePattern *pattern;
     /// The current benefit of the pattern that was matched.
     PatternBenefit benefit;
   };

   /// Create a ByteCode instance from the given module containing operations in
   /// the PDL interpreter dialect.
   PDLByteCode(ModuleOp module,
               llvm::StringMap<PDLConstraintFunction> constraintFns,
               llvm::StringMap<PDLRewriteFunction> rewriteFns);

   /// Return the patterns held by the bytecode.
   ArrayRef<PDLByteCodePattern> getPatterns() const { return patterns; }

   /// Initialize the given state such that it can be used to execute the current
   /// bytecode.
   void initializeMutableState(PDLByteCodeMutableState &state) const;

   /// Run the pattern matcher on the given root operation, collecting the
   /// matched patterns in `matches`.
   void match(Operation *op, PatternRewriter &rewriter,
              SmallVectorImpl<MatchResult> &matches,
              PDLByteCodeMutableState &state) const;

   /// Run the rewriter of the given pattern that was previously matched in
   /// `match`.
   void rewrite(PatternRewriter &rewriter, const MatchResult &match,
                PDLByteCodeMutableState &state) const;

 private:
   /// Execute the given byte code starting at the provided instruction `inst`.
   /// `matches` is an optional field provided when this function is executed in
   /// a matching context.
   void executeByteCode(const ByteCodeField *inst, PatternRewriter &rewriter,
                        PDLByteCodeMutableState &state,
                        SmallVectorImpl<MatchResult> *matches) const;

   /// A vector containing pointers to uniqued data. The storage is intentionally
   /// opaque such that we can store a wide range of data types. The types of
   /// data stored here include:
   ///  * Attribute, OperationName, Type
   std::vector<const void *> uniquedData;

   /// A vector containing the generated bytecode for the matcher.
   SmallVector<ByteCodeField, 64> matcherByteCode;

   /// A vector containing the generated bytecode for all of the rewriters.
   SmallVector<ByteCodeField, 64> rewriterByteCode;

   /// The set of patterns contained within the bytecode.
   SmallVector<PDLByteCodePattern, 32> patterns;

   /// A set of user defined functions invoked via PDL.
   std::vector<PDLConstraintFunction> constraintFunctions;
   std::vector<PDLRewriteFunction> rewriteFunctions;

   /// The maximum memory index used by a value.
   ByteCodeField maxValueMemoryIndex = 0;

   /// The maximum number of different types of ranges.
   ByteCodeField maxOpRangeCount = 0;
   ByteCodeField maxTypeRangeCount = 0;
   ByteCodeField maxValueRangeCount = 0;

   /// The maximum number of nested loops.
   ByteCodeField maxLoopLevel = 0;
 };

 } // end namespace detail
 } // end namespace mlir

 #endif // MLIR_REWRITE_BYTECODE_H_
	//===- ByteCode.h - Pattern byte-code interpreter ---------------- 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
	//
	//===----------------------------------------------------------------------===//
	//
	// This file declares a byte-code and interpreter for pattern rewrites in MLIR.
	// The byte-code is constructed from the PDL Interpreter dialect.
	//
	//===----------------------------------------------------------------------===//

	#ifndef MLIR_REWRITE_BYTECODE_H_
	#define MLIR_REWRITE_BYTECODE_H_

	#include "mlir/IR/PatternMatch.h"

	namespace mlir {
	namespace pdl_interp {
	class RecordMatchOp;
	} // end namespace pdl_interp

	namespace detail {
	class PDLByteCode;

	/// Use generic bytecode types. ByteCodeField refers to the actual bytecode
	/// entries. ByteCodeAddr refers to size of indices into the bytecode.
	using ByteCodeField = uint16_t;
	using ByteCodeAddr = uint32_t;
	using OwningOpRange = llvm::OwningArrayRef<Operation *>;

	//===----------------------------------------------------------------------===//
	// PDLByteCodePattern
	//===----------------------------------------------------------------------===//

	/// All of the data pertaining to a specific pattern within the bytecode.
	class PDLByteCodePattern : public Pattern {
	public:
	static PDLByteCodePattern create(pdl_interp::RecordMatchOp matchOp,
	ByteCodeAddr rewriterAddr);

	/// Return the bytecode address of the rewriter for this pattern.
	ByteCodeAddr getRewriterAddr() const { return rewriterAddr; }

	private:
	template <typename... Args>
	PDLByteCodePattern(ByteCodeAddr rewriterAddr, Args &&...patternArgs)
	: Pattern(std::forward<Args>(patternArgs)...),
	rewriterAddr(rewriterAddr) {}

	/// The address of the rewriter for this pattern.
	ByteCodeAddr rewriterAddr;
	};

	//===----------------------------------------------------------------------===//
	// PDLByteCodeMutableState
	//===----------------------------------------------------------------------===//

	/// This class contains the mutable state of a bytecode instance. This allows
	/// for a bytecode instance to be cached and reused across various different
	/// threads/drivers.
	class PDLByteCodeMutableState {
	public:
	/// Set the new benefit for a bytecode pattern. The `patternIndex` corresponds
	/// to the position of the pattern within the range returned by
	/// `PDLByteCode::getPatterns`.
	void updatePatternBenefit(unsigned patternIndex, PatternBenefit benefit);

	/// Cleanup any allocated state after a match/rewrite has been completed. This
	/// method should be called irregardless of whether the match+rewrite was a
	/// success or not.
	void cleanupAfterMatchAndRewrite();

	private:
	/// Allow access to data fields.
	friend class PDLByteCode;

	/// The mutable block of memory used during the matching and rewriting phases
	/// of the bytecode.
	std::vector<const void *> memory;

	/// A mutable block of memory used during the matching and rewriting phase of
	/// the bytecode to store ranges of operations. These are always stored by
	/// owning references, because at no point in the execution of the byte code
	/// we get an indexed range (view) of operations.
	std::vector<OwningOpRange> opRangeMemory;

	/// A mutable block of memory used during the matching and rewriting phase of
	/// the bytecode to store ranges of types.
	std::vector<TypeRange> typeRangeMemory;
	/// A set of type ranges that have been allocated by the byte code interpreter
	/// to provide a guaranteed lifetime.
	std::vector<llvm::OwningArrayRef<Type>> allocatedTypeRangeMemory;

	/// A mutable block of memory used during the matching and rewriting phase of
	/// the bytecode to store ranges of values.
	std::vector<ValueRange> valueRangeMemory;
	/// A set of value ranges that have been allocated by the byte code
	/// interpreter to provide a guaranteed lifetime.
	std::vector<llvm::OwningArrayRef<Value>> allocatedValueRangeMemory;

	/// The current index of ranges being iterated over for each level of nesting.
	/// These are always maintained at 0 for the loops that are not active, so we
	/// do not need to have a separate initialization phase for each loop.
	std::vector<unsigned> loopIndex;

	/// The up-to-date benefits of the patterns held by the bytecode. The order
	/// of this array corresponds 1-1 with the array of patterns in `PDLByteCode`.
	std::vector<PatternBenefit> currentPatternBenefits;
	};

	//===----------------------------------------------------------------------===//
	// PDLByteCode
	//===----------------------------------------------------------------------===//

	/// The bytecode class is also the interpreter. Contains the bytecode itself,
	/// the static info, addresses of the rewriter functions, the interpreter
	/// memory buffer, and the execution context.
	class PDLByteCode {
	public:
	/// Each successful match returns a MatchResult, which contains information
	/// necessary to execute the rewriter and indicates the originating pattern.
	struct MatchResult {
	MatchResult(Location loc, const PDLByteCodePattern &pattern,
	PatternBenefit benefit)
	: location(loc), pattern(&pattern), benefit(benefit) {}
	MatchResult(const MatchResult &) = delete;
	MatchResult &operator=(const MatchResult &) = delete;
	MatchResult(MatchResult &&other) = default;
	MatchResult &operator=(MatchResult &&) = default;

	/// The location of operations to be replaced.
	Location location;
	/// Memory values defined in the matcher that are passed to the rewriter.
	SmallVector<const void *> values;
	/// Memory used for the range input values.
	SmallVector<TypeRange, 0> typeRangeValues;
	SmallVector<ValueRange, 0> valueRangeValues;

	/// The originating pattern that was matched. This is always non-null, but
	/// represented with a pointer to allow for assignment.
	const PDLByteCodePattern *pattern;
	/// The current benefit of the pattern that was matched.
	PatternBenefit benefit;
	};

	/// Create a ByteCode instance from the given module containing operations in
	/// the PDL interpreter dialect.
	PDLByteCode(ModuleOp module,
	llvm::StringMap<PDLConstraintFunction> constraintFns,
	llvm::StringMap<PDLRewriteFunction> rewriteFns);

	/// Return the patterns held by the bytecode.
	ArrayRef<PDLByteCodePattern> getPatterns() const { return patterns; }

	/// Initialize the given state such that it can be used to execute the current
	/// bytecode.
	void initializeMutableState(PDLByteCodeMutableState &state) const;

	/// Run the pattern matcher on the given root operation, collecting the
	/// matched patterns in `matches`.
	void match(Operation *op, PatternRewriter &rewriter,
	SmallVectorImpl<MatchResult> &matches,
	PDLByteCodeMutableState &state) const;

	/// Run the rewriter of the given pattern that was previously matched in
	/// `match`.
	void rewrite(PatternRewriter &rewriter, const MatchResult &match,
	PDLByteCodeMutableState &state) const;

	private:
	/// Execute the given byte code starting at the provided instruction `inst`.
	/// `matches` is an optional field provided when this function is executed in
	/// a matching context.
	void executeByteCode(const ByteCodeField *inst, PatternRewriter &rewriter,
	PDLByteCodeMutableState &state,
	SmallVectorImpl<MatchResult> *matches) const;

	/// A vector containing pointers to uniqued data. The storage is intentionally
	/// opaque such that we can store a wide range of data types. The types of
	/// data stored here include:
	/// * Attribute, OperationName, Type
	std::vector<const void *> uniquedData;

	/// A vector containing the generated bytecode for the matcher.
	SmallVector<ByteCodeField, 64> matcherByteCode;

	/// A vector containing the generated bytecode for all of the rewriters.
	SmallVector<ByteCodeField, 64> rewriterByteCode;

	/// The set of patterns contained within the bytecode.
	SmallVector<PDLByteCodePattern, 32> patterns;

	/// A set of user defined functions invoked via PDL.
	std::vector<PDLConstraintFunction> constraintFunctions;
	std::vector<PDLRewriteFunction> rewriteFunctions;

	/// The maximum memory index used by a value.
	ByteCodeField maxValueMemoryIndex = 0;

	/// The maximum number of different types of ranges.
	ByteCodeField maxOpRangeCount = 0;
	ByteCodeField maxTypeRangeCount = 0;
	ByteCodeField maxValueRangeCount = 0;

	/// The maximum number of nested loops.
	ByteCodeField maxLoopLevel = 0;
	};

	} // end namespace detail
	} // end namespace mlir

	#endif // MLIR_REWRITE_BYTECODE_H_