linux-x64/clang/include/llvm/Transforms/IPO/LowerTypeTests.h - hafnium/prebuilts - Git at Google

 //===- LowerTypeTests.h - type metadata lowering pass -----------*- C++ -*-===//
 //
 //                     The LLVM Compiler Infrastructure
 //
 // This file is distributed under the University of Illinois Open Source
 // License. See LICENSE.TXT for details.
 //
 //===----------------------------------------------------------------------===//
 //
 // This file defines parts of the type test lowering pass implementation that
 // may be usefully unit tested.
 //
 //===----------------------------------------------------------------------===//

 #ifndef LLVM_TRANSFORMS_IPO_LOWERTYPETESTS_H
 #define LLVM_TRANSFORMS_IPO_LOWERTYPETESTS_H

 #include "llvm/ADT/SmallVector.h"
 #include "llvm/IR/PassManager.h"
 #include <cstdint>
 #include <cstring>
 #include <limits>
 #include <set>
 #include <vector>

 namespace llvm {

 class Module;
 class raw_ostream;

 namespace lowertypetests {

 struct BitSetInfo {
   // The indices of the set bits in the bitset.
   std::set<uint64_t> Bits;

   // The byte offset into the combined global represented by the bitset.
   uint64_t ByteOffset;

   // The size of the bitset in bits.
   uint64_t BitSize;

   // Log2 alignment of the bit set relative to the combined global.
   // For example, a log2 alignment of 3 means that bits in the bitset
   // represent addresses 8 bytes apart.
   unsigned AlignLog2;

   bool isSingleOffset() const {
     return Bits.size() == 1;
   }

   bool isAllOnes() const {
     return Bits.size() == BitSize;
   }

   bool containsGlobalOffset(uint64_t Offset) const;

   void print(raw_ostream &OS) const;
 };

 struct BitSetBuilder {
   SmallVector<uint64_t, 16> Offsets;
   uint64_t Min = std::numeric_limits<uint64_t>::max();
   uint64_t Max = 0;

   BitSetBuilder() = default;

   void addOffset(uint64_t Offset) {
     if (Min > Offset)
       Min = Offset;
     if (Max < Offset)
       Max = Offset;

     Offsets.push_back(Offset);
   }

   BitSetInfo build();
 };

 /// This class implements a layout algorithm for globals referenced by bit sets
 /// that tries to keep members of small bit sets together. This can
 /// significantly reduce bit set sizes in many cases.
 ///
 /// It works by assembling fragments of layout from sets of referenced globals.
 /// Each set of referenced globals causes the algorithm to create a new
 /// fragment, which is assembled by appending each referenced global in the set
 /// into the fragment. If a referenced global has already been referenced by an
 /// fragment created earlier, we instead delete that fragment and append its
 /// contents into the fragment we are assembling.
 ///
 /// By starting with the smallest fragments, we minimize the size of the
 /// fragments that are copied into larger fragments. This is most intuitively
 /// thought about when considering the case where the globals are virtual tables
 /// and the bit sets represent their derived classes: in a single inheritance
 /// hierarchy, the optimum layout would involve a depth-first search of the
 /// class hierarchy (and in fact the computed layout ends up looking a lot like
 /// a DFS), but a naive DFS would not work well in the presence of multiple
 /// inheritance. This aspect of the algorithm ends up fitting smaller
 /// hierarchies inside larger ones where that would be beneficial.
 ///
 /// For example, consider this class hierarchy:
 ///
 /// A       B
 ///   \   / | \
 ///     C   D   E
 ///
 /// We have five bit sets: bsA (A, C), bsB (B, C, D, E), bsC (C), bsD (D) and
 /// bsE (E). If we laid out our objects by DFS traversing B followed by A, our
 /// layout would be {B, C, D, E, A}. This is optimal for bsB as it needs to
 /// cover the only 4 objects in its hierarchy, but not for bsA as it needs to
 /// cover 5 objects, i.e. the entire layout. Our algorithm proceeds as follows:
 ///
 /// Add bsC, fragments {{C}}
 /// Add bsD, fragments {{C}, {D}}
 /// Add bsE, fragments {{C}, {D}, {E}}
 /// Add bsA, fragments {{A, C}, {D}, {E}}
 /// Add bsB, fragments {{B, A, C, D, E}}
 ///
 /// This layout is optimal for bsA, as it now only needs to cover two (i.e. 3
 /// fewer) objects, at the cost of bsB needing to cover 1 more object.
 ///
 /// The bit set lowering pass assigns an object index to each object that needs
 /// to be laid out, and calls addFragment for each bit set passing the object
 /// indices of its referenced globals. It then assembles a layout from the
 /// computed layout in the Fragments field.
 struct GlobalLayoutBuilder {
   /// The computed layout. Each element of this vector contains a fragment of
   /// layout (which may be empty) consisting of object indices.
   std::vector<std::vector<uint64_t>> Fragments;

   /// Mapping from object index to fragment index.
   std::vector<uint64_t> FragmentMap;

   GlobalLayoutBuilder(uint64_t NumObjects)
       : Fragments(1), FragmentMap(NumObjects) {}

   /// Add F to the layout while trying to keep its indices contiguous.
   /// If a previously seen fragment uses any of F's indices, that
   /// fragment will be laid out inside F.
   void addFragment(const std::set<uint64_t> &F);
 };

 /// This class is used to build a byte array containing overlapping bit sets. By
 /// loading from indexed offsets into the byte array and applying a mask, a
 /// program can test bits from the bit set with a relatively short instruction
 /// sequence. For example, suppose we have 15 bit sets to lay out:
 ///
 /// A (16 bits), B (15 bits), C (14 bits), D (13 bits), E (12 bits),
 /// F (11 bits), G (10 bits), H (9 bits), I (7 bits), J (6 bits), K (5 bits),
 /// L (4 bits), M (3 bits), N (2 bits), O (1 bit)
 ///
 /// These bits can be laid out in a 16-byte array like this:
 ///
 ///       Byte Offset
 ///     0123456789ABCDEF
 /// Bit
 ///   7 HHHHHHHHHIIIIIII
 ///   6 GGGGGGGGGGJJJJJJ
 ///   5 FFFFFFFFFFFKKKKK
 ///   4 EEEEEEEEEEEELLLL
 ///   3 DDDDDDDDDDDDDMMM
 ///   2 CCCCCCCCCCCCCCNN
 ///   1 BBBBBBBBBBBBBBBO
 ///   0 AAAAAAAAAAAAAAAA
 ///
 /// For example, to test bit X of A, we evaluate ((bits[X] & 1) != 0), or to
 /// test bit X of I, we evaluate ((bits[9 + X] & 0x80) != 0). This can be done
 /// in 1-2 machine instructions on x86, or 4-6 instructions on ARM.
 ///
 /// This is a byte array, rather than (say) a 2-byte array or a 4-byte array,
 /// because for one thing it gives us better packing (the more bins there are,
 /// the less evenly they will be filled), and for another, the instruction
 /// sequences can be slightly shorter, both on x86 and ARM.
 struct ByteArrayBuilder {
   /// The byte array built so far.
   std::vector<uint8_t> Bytes;

   enum { BitsPerByte = 8 };

   /// The number of bytes allocated so far for each of the bits.
   uint64_t BitAllocs[BitsPerByte];

   ByteArrayBuilder() {
     memset(BitAllocs, 0, sizeof(BitAllocs));
   }

   /// Allocate BitSize bits in the byte array where Bits contains the bits to
   /// set. AllocByteOffset is set to the offset within the byte array and
   /// AllocMask is set to the bitmask for those bits. This uses the LPT (Longest
   /// Processing Time) multiprocessor scheduling algorithm to lay out the bits
   /// efficiently; the pass allocates bit sets in decreasing size order.
   void allocate(const std::set<uint64_t> &Bits, uint64_t BitSize,
                 uint64_t &AllocByteOffset, uint8_t &AllocMask);
 };

 } // end namespace lowertypetests

 class LowerTypeTestsPass : public PassInfoMixin<LowerTypeTestsPass> {
 public:
   PreservedAnalyses run(Module &M, ModuleAnalysisManager &AM);
 };

 } // end namespace llvm

 #endif // LLVM_TRANSFORMS_IPO_LOWERTYPETESTS_H
	//===- LowerTypeTests.h - type metadata lowering pass ------------ C++ --===//
	//
	// The LLVM Compiler Infrastructure
	//
	// This file is distributed under the University of Illinois Open Source
	// License. See LICENSE.TXT for details.
	//
	//===----------------------------------------------------------------------===//
	//
	// This file defines parts of the type test lowering pass implementation that
	// may be usefully unit tested.
	//
	//===----------------------------------------------------------------------===//

	#ifndef LLVM_TRANSFORMS_IPO_LOWERTYPETESTS_H
	#define LLVM_TRANSFORMS_IPO_LOWERTYPETESTS_H

	#include "llvm/ADT/SmallVector.h"
	#include "llvm/IR/PassManager.h"
	#include <cstdint>
	#include <cstring>
	#include <limits>
	#include <set>
	#include <vector>

	namespace llvm {

	class Module;
	class raw_ostream;

	namespace lowertypetests {

	struct BitSetInfo {
	// The indices of the set bits in the bitset.
	std::set<uint64_t> Bits;

	// The byte offset into the combined global represented by the bitset.
	uint64_t ByteOffset;

	// The size of the bitset in bits.
	uint64_t BitSize;

	// Log2 alignment of the bit set relative to the combined global.
	// For example, a log2 alignment of 3 means that bits in the bitset
	// represent addresses 8 bytes apart.
	unsigned AlignLog2;

	bool isSingleOffset() const {
	return Bits.size() == 1;
	}

	bool isAllOnes() const {
	return Bits.size() == BitSize;
	}

	bool containsGlobalOffset(uint64_t Offset) const;

	void print(raw_ostream &OS) const;
	};

	struct BitSetBuilder {
	SmallVector<uint64_t, 16> Offsets;
	uint64_t Min = std::numeric_limits<uint64_t>::max();
	uint64_t Max = 0;

	BitSetBuilder() = default;

	void addOffset(uint64_t Offset) {
	if (Min > Offset)
	Min = Offset;
	if (Max < Offset)
	Max = Offset;

	Offsets.push_back(Offset);
	}

	BitSetInfo build();
	};

	/// This class implements a layout algorithm for globals referenced by bit sets
	/// that tries to keep members of small bit sets together. This can
	/// significantly reduce bit set sizes in many cases.
	///
	/// It works by assembling fragments of layout from sets of referenced globals.
	/// Each set of referenced globals causes the algorithm to create a new
	/// fragment, which is assembled by appending each referenced global in the set
	/// into the fragment. If a referenced global has already been referenced by an
	/// fragment created earlier, we instead delete that fragment and append its
	/// contents into the fragment we are assembling.
	///
	/// By starting with the smallest fragments, we minimize the size of the
	/// fragments that are copied into larger fragments. This is most intuitively
	/// thought about when considering the case where the globals are virtual tables
	/// and the bit sets represent their derived classes: in a single inheritance
	/// hierarchy, the optimum layout would involve a depth-first search of the
	/// class hierarchy (and in fact the computed layout ends up looking a lot like
	/// a DFS), but a naive DFS would not work well in the presence of multiple
	/// inheritance. This aspect of the algorithm ends up fitting smaller
	/// hierarchies inside larger ones where that would be beneficial.
	///
	/// For example, consider this class hierarchy:
	///
	/// A B
	/// \ / \| \
	/// C D E
	///
	/// We have five bit sets: bsA (A, C), bsB (B, C, D, E), bsC (C), bsD (D) and
	/// bsE (E). If we laid out our objects by DFS traversing B followed by A, our
	/// layout would be {B, C, D, E, A}. This is optimal for bsB as it needs to
	/// cover the only 4 objects in its hierarchy, but not for bsA as it needs to
	/// cover 5 objects, i.e. the entire layout. Our algorithm proceeds as follows:
	///
	/// Add bsC, fragments {{C}}
	/// Add bsD, fragments {{C}, {D}}
	/// Add bsE, fragments {{C}, {D}, {E}}
	/// Add bsA, fragments {{A, C}, {D}, {E}}
	/// Add bsB, fragments {{B, A, C, D, E}}
	///
	/// This layout is optimal for bsA, as it now only needs to cover two (i.e. 3
	/// fewer) objects, at the cost of bsB needing to cover 1 more object.
	///
	/// The bit set lowering pass assigns an object index to each object that needs
	/// to be laid out, and calls addFragment for each bit set passing the object
	/// indices of its referenced globals. It then assembles a layout from the
	/// computed layout in the Fragments field.
	struct GlobalLayoutBuilder {
	/// The computed layout. Each element of this vector contains a fragment of
	/// layout (which may be empty) consisting of object indices.
	std::vector<std::vector<uint64_t>> Fragments;

	/// Mapping from object index to fragment index.
	std::vector<uint64_t> FragmentMap;

	GlobalLayoutBuilder(uint64_t NumObjects)
	: Fragments(1), FragmentMap(NumObjects) {}

	/// Add F to the layout while trying to keep its indices contiguous.
	/// If a previously seen fragment uses any of F's indices, that
	/// fragment will be laid out inside F.
	void addFragment(const std::set<uint64_t> &F);
	};

	/// This class is used to build a byte array containing overlapping bit sets. By
	/// loading from indexed offsets into the byte array and applying a mask, a
	/// program can test bits from the bit set with a relatively short instruction
	/// sequence. For example, suppose we have 15 bit sets to lay out:
	///
	/// A (16 bits), B (15 bits), C (14 bits), D (13 bits), E (12 bits),
	/// F (11 bits), G (10 bits), H (9 bits), I (7 bits), J (6 bits), K (5 bits),
	/// L (4 bits), M (3 bits), N (2 bits), O (1 bit)
	///
	/// These bits can be laid out in a 16-byte array like this:
	///
	/// Byte Offset
	/// 0123456789ABCDEF
	/// Bit
	/// 7 HHHHHHHHHIIIIIII
	/// 6 GGGGGGGGGGJJJJJJ
	/// 5 FFFFFFFFFFFKKKKK
	/// 4 EEEEEEEEEEEELLLL
	/// 3 DDDDDDDDDDDDDMMM
	/// 2 CCCCCCCCCCCCCCNN
	/// 1 BBBBBBBBBBBBBBBO
	/// 0 AAAAAAAAAAAAAAAA
	///
	/// For example, to test bit X of A, we evaluate ((bits[X] & 1) != 0), or to
	/// test bit X of I, we evaluate ((bits[9 + X] & 0x80) != 0). This can be done
	/// in 1-2 machine instructions on x86, or 4-6 instructions on ARM.
	///
	/// This is a byte array, rather than (say) a 2-byte array or a 4-byte array,
	/// because for one thing it gives us better packing (the more bins there are,
	/// the less evenly they will be filled), and for another, the instruction
	/// sequences can be slightly shorter, both on x86 and ARM.
	struct ByteArrayBuilder {
	/// The byte array built so far.
	std::vector<uint8_t> Bytes;

	enum { BitsPerByte = 8 };

	/// The number of bytes allocated so far for each of the bits.
	uint64_t BitAllocs[BitsPerByte];

	ByteArrayBuilder() {
	memset(BitAllocs, 0, sizeof(BitAllocs));
	}

	/// Allocate BitSize bits in the byte array where Bits contains the bits to
	/// set. AllocByteOffset is set to the offset within the byte array and
	/// AllocMask is set to the bitmask for those bits. This uses the LPT (Longest
	/// Processing Time) multiprocessor scheduling algorithm to lay out the bits
	/// efficiently; the pass allocates bit sets in decreasing size order.
	void allocate(const std::set<uint64_t> &Bits, uint64_t BitSize,
	uint64_t &AllocByteOffset, uint8_t &AllocMask);
	};

	} // end namespace lowertypetests

	class LowerTypeTestsPass : public PassInfoMixin<LowerTypeTestsPass> {
	public:
	PreservedAnalyses run(Module &M, ModuleAnalysisManager &AM);
	};

	} // end namespace llvm

	#endif // LLVM_TRANSFORMS_IPO_LOWERTYPETESTS_H