third_party/llvm-7.0/llvm/utils/PerfectShuffle/PerfectShuffle.cpp - SwiftShader - Git at Google

 //===-- PerfectShuffle.cpp - Perfect Shuffle Generator --------------------===//
 //
 //                     The LLVM Compiler Infrastructure
 //
 // This file is distributed under the University of Illinois Open Source
 // License. See LICENSE.TXT for details.
 //
 //===----------------------------------------------------------------------===//
 //
 // This file computes an optimal sequence of instructions for doing all shuffles
 // of two 4-element vectors.  With a release build and when configured to emit
 // an altivec instruction table, this takes about 30s to run on a 2.7Ghz
 // PowerPC G5.
 //
 //===----------------------------------------------------------------------===//

 #include <cassert>
 #include <cstdlib>
 #include <iomanip>
 #include <iostream>
 #include <vector>
 struct Operator;

 // Masks are 4-nibble hex numbers.  Values 0-7 in any nibble means that it takes
 // an element from that value of the input vectors.  A value of 8 means the
 // entry is undefined.

 // Mask manipulation functions.
 static inline unsigned short MakeMask(unsigned V0, unsigned V1,
                                       unsigned V2, unsigned V3) {
   return (V0 << (3*4)) | (V1 << (2*4)) | (V2 << (1*4)) | (V3 << (0*4));
 }

 /// getMaskElt - Return element N of the specified mask.
 static unsigned getMaskElt(unsigned Mask, unsigned Elt) {
   return (Mask >> ((3-Elt)*4)) & 0xF;
 }

 static unsigned setMaskElt(unsigned Mask, unsigned Elt, unsigned NewVal) {
   unsigned FieldShift = ((3-Elt)*4);
   return (Mask & ~(0xF << FieldShift)) | (NewVal << FieldShift);
 }

 // Reject elements where the values are 9-15.
 static bool isValidMask(unsigned short Mask) {
   unsigned short UndefBits = Mask & 0x8888;
   return (Mask & ((UndefBits >> 1)|(UndefBits>>2)|(UndefBits>>3))) == 0;
 }

 /// hasUndefElements - Return true if any of the elements in the mask are undefs
 ///
 static bool hasUndefElements(unsigned short Mask) {
   return (Mask & 0x8888) != 0;
 }

 /// isOnlyLHSMask - Return true if this mask only refers to its LHS, not
 /// including undef values..
 static bool isOnlyLHSMask(unsigned short Mask) {
   return (Mask & 0x4444) == 0;
 }

 /// getLHSOnlyMask - Given a mask that refers to its LHS and RHS, modify it to
 /// refer to the LHS only (for when one argument value is passed into the same
 /// function twice).
 #if 0
 static unsigned short getLHSOnlyMask(unsigned short Mask) {
   return Mask & 0xBBBB;  // Keep only LHS and Undefs.
 }
 #endif

 /// getCompressedMask - Turn a 16-bit uncompressed mask (where each elt uses 4
 /// bits) into a compressed 13-bit mask, where each elt is multiplied by 9.
 static unsigned getCompressedMask(unsigned short Mask) {
   return getMaskElt(Mask, 0)*9*9*9 + getMaskElt(Mask, 1)*9*9 +
          getMaskElt(Mask, 2)*9     + getMaskElt(Mask, 3);
 }

 static void PrintMask(unsigned i, std::ostream &OS) {
   OS << "<" << (char)(getMaskElt(i, 0) == 8 ? 'u' : ('0'+getMaskElt(i, 0)))
      << "," << (char)(getMaskElt(i, 1) == 8 ? 'u' : ('0'+getMaskElt(i, 1)))
      << "," << (char)(getMaskElt(i, 2) == 8 ? 'u' : ('0'+getMaskElt(i, 2)))
      << "," << (char)(getMaskElt(i, 3) == 8 ? 'u' : ('0'+getMaskElt(i, 3)))
      << ">";
 }

 /// ShuffleVal - This represents a shufflevector operation.
 struct ShuffleVal {
   Operator *Op;   // The Operation used to generate this value.
   unsigned Cost;  // Number of instrs used to generate this value.
   unsigned short Arg0, Arg1;  // Input operands for this value.

   ShuffleVal() : Cost(1000000) {}
 };


 /// ShufTab - This is the actual shuffle table that we are trying to generate.
 ///
 static ShuffleVal ShufTab[65536];

 /// TheOperators - All of the operators that this target supports.
 static std::vector<Operator*> TheOperators;

 /// Operator - This is a vector operation that is available for use.
 struct Operator {
   const char *Name;
   unsigned short ShuffleMask;
   unsigned short OpNum;
   unsigned Cost;

   Operator(unsigned short shufflemask, const char *name, unsigned opnum,
            unsigned cost = 1)
     :  Name(name), ShuffleMask(shufflemask), OpNum(opnum),Cost(cost) {
     TheOperators.push_back(this);
   }
   ~Operator() {
     assert(TheOperators.back() == this);
     TheOperators.pop_back();
   }

   bool isOnlyLHSOperator() const {
     return isOnlyLHSMask(ShuffleMask);
   }

   const char *getName() const { return Name; }
   unsigned getCost() const { return Cost; }

   unsigned short getTransformedMask(unsigned short LHSMask, unsigned RHSMask) {
     // Extract the elements from LHSMask and RHSMask, as appropriate.
     unsigned Result = 0;
     for (unsigned i = 0; i != 4; ++i) {
       unsigned SrcElt = (ShuffleMask >> (4*i)) & 0xF;
       unsigned ResElt;
       if (SrcElt < 4)
         ResElt = getMaskElt(LHSMask, SrcElt);
       else if (SrcElt < 8)
         ResElt = getMaskElt(RHSMask, SrcElt-4);
       else {
         assert(SrcElt == 8 && "Bad src elt!");
         ResElt = 8;
       }
       Result |= ResElt << (4*i);
     }
     return Result;
   }
 };

 static const char *getZeroCostOpName(unsigned short Op) {
   if (ShufTab[Op].Arg0 == 0x0123)
     return "LHS";
   else if (ShufTab[Op].Arg0 == 0x4567)
     return "RHS";
   else {
     assert(0 && "bad zero cost operation");
     abort();
   }
 }

 static void PrintOperation(unsigned ValNo, unsigned short Vals[]) {
   unsigned short ThisOp = Vals[ValNo];
   std::cerr << "t" << ValNo;
   PrintMask(ThisOp, std::cerr);
   std::cerr << " = " << ShufTab[ThisOp].Op->getName() << "(";

   if (ShufTab[ShufTab[ThisOp].Arg0].Cost == 0) {
     std::cerr << getZeroCostOpName(ShufTab[ThisOp].Arg0);
     PrintMask(ShufTab[ThisOp].Arg0, std::cerr);
   } else {
     // Figure out what tmp # it is.
     for (unsigned i = 0; ; ++i)
       if (Vals[i] == ShufTab[ThisOp].Arg0) {
         std::cerr << "t" << i;
         break;
       }
   }

   if (!ShufTab[Vals[ValNo]].Op->isOnlyLHSOperator()) {
     std::cerr << ", ";
     if (ShufTab[ShufTab[ThisOp].Arg1].Cost == 0) {
       std::cerr << getZeroCostOpName(ShufTab[ThisOp].Arg1);
       PrintMask(ShufTab[ThisOp].Arg1, std::cerr);
     } else {
       // Figure out what tmp # it is.
       for (unsigned i = 0; ; ++i)
         if (Vals[i] == ShufTab[ThisOp].Arg1) {
           std::cerr << "t" << i;
           break;
         }
     }
   }
   std::cerr << ")  ";
 }

 static unsigned getNumEntered() {
   unsigned Count = 0;
   for (unsigned i = 0; i != 65536; ++i)
     Count += ShufTab[i].Cost < 100;
   return Count;
 }

 static void EvaluateOps(unsigned short Elt, unsigned short Vals[],
                         unsigned &NumVals) {
   if (ShufTab[Elt].Cost == 0) return;

   // If this value has already been evaluated, it is free.  FIXME: match undefs.
   for (unsigned i = 0, e = NumVals; i != e; ++i)
     if (Vals[i] == Elt) return;

   // Otherwise, get the operands of the value, then add it.
   unsigned Arg0 = ShufTab[Elt].Arg0, Arg1 = ShufTab[Elt].Arg1;
   if (ShufTab[Arg0].Cost)
     EvaluateOps(Arg0, Vals, NumVals);
   if (Arg0 != Arg1 && ShufTab[Arg1].Cost)
     EvaluateOps(Arg1, Vals, NumVals);

   Vals[NumVals++] = Elt;
 }


 int main() {
   // Seed the table with accesses to the LHS and RHS.
   ShufTab[0x0123].Cost = 0;
   ShufTab[0x0123].Op = nullptr;
   ShufTab[0x0123].Arg0 = 0x0123;
   ShufTab[0x4567].Cost = 0;
   ShufTab[0x4567].Op = nullptr;
   ShufTab[0x4567].Arg0 = 0x4567;

   // Seed the first-level of shuffles, shuffles whose inputs are the input to
   // the vectorshuffle operation.
   bool MadeChange = true;
   unsigned OpCount = 0;
   while (MadeChange) {
     MadeChange = false;
     ++OpCount;
     std::cerr << "Starting iteration #" << OpCount << " with "
               << getNumEntered() << " entries established.\n";

     // Scan the table for two reasons: First, compute the maximum cost of any
     // operation left in the table.  Second, make sure that values with undefs
     // have the cheapest alternative that they match.
     unsigned MaxCost = ShufTab[0].Cost;
     for (unsigned i = 1; i != 0x8889; ++i) {
       if (!isValidMask(i)) continue;
       if (ShufTab[i].Cost > MaxCost)
         MaxCost = ShufTab[i].Cost;

       // If this value has an undef, make it be computed the cheapest possible
       // way of any of the things that it matches.
       if (hasUndefElements(i)) {
         // This code is a little bit tricky, so here's the idea: consider some
         // permutation, like 7u4u.  To compute the lowest cost for 7u4u, we
         // need to take the minimum cost of all of 7[0-8]4[0-8], 81 entries.  If
         // there are 3 undefs, the number rises to 729 entries we have to scan,
         // and for the 4 undef case, we have to scan the whole table.
         //
         // Instead of doing this huge amount of scanning, we process the table
         // entries *in order*, and use the fact that 'u' is 8, larger than any
         // valid index.  Given an entry like 7u4u then, we only need to scan
         // 7[0-7]4u - 8 entries.  We can get away with this, because we already
         // know that each of 704u, 714u, 724u, etc contain the minimum value of
         // all of the 704[0-8], 714[0-8] and 724[0-8] entries respectively.
         unsigned UndefIdx;
         if (i & 0x8000)
           UndefIdx = 0;
         else if (i & 0x0800)
           UndefIdx = 1;
         else if (i & 0x0080)
           UndefIdx = 2;
         else if (i & 0x0008)
           UndefIdx = 3;
         else
           abort();

         unsigned MinVal  = i;
         unsigned MinCost = ShufTab[i].Cost;

         // Scan the 8 entries.
         for (unsigned j = 0; j != 8; ++j) {
           unsigned NewElt = setMaskElt(i, UndefIdx, j);
           if (ShufTab[NewElt].Cost < MinCost) {
             MinCost = ShufTab[NewElt].Cost;
             MinVal = NewElt;
           }
         }

         // If we found something cheaper than what was here before, use it.
         if (i != MinVal) {
           MadeChange = true;
           ShufTab[i] = ShufTab[MinVal];
         }
       }
     }

     for (unsigned LHS = 0; LHS != 0x8889; ++LHS) {
       if (!isValidMask(LHS)) continue;
       if (ShufTab[LHS].Cost > 1000) continue;

       // If nothing involving this operand could possibly be cheaper than what
       // we already have, don't consider it.
       if (ShufTab[LHS].Cost + 1 >= MaxCost)
         continue;

       for (unsigned opnum = 0, e = TheOperators.size(); opnum != e; ++opnum) {
         Operator *Op = TheOperators[opnum];

         // Evaluate op(LHS,LHS)
         unsigned ResultMask = Op->getTransformedMask(LHS, LHS);

         unsigned Cost = ShufTab[LHS].Cost + Op->getCost();
         if (Cost < ShufTab[ResultMask].Cost) {
           ShufTab[ResultMask].Cost = Cost;
           ShufTab[ResultMask].Op = Op;
           ShufTab[ResultMask].Arg0 = LHS;
           ShufTab[ResultMask].Arg1 = LHS;
           MadeChange = true;
         }

         // If this is a two input instruction, include the op(x,y) cases.  If
         // this is a one input instruction, skip this.
         if (Op->isOnlyLHSOperator()) continue;

         for (unsigned RHS = 0; RHS != 0x8889; ++RHS) {
           if (!isValidMask(RHS)) continue;
           if (ShufTab[RHS].Cost > 1000) continue;

           // If nothing involving this operand could possibly be cheaper than
           // what we already have, don't consider it.
           if (ShufTab[RHS].Cost + 1 >= MaxCost)
             continue;


           // Evaluate op(LHS,RHS)
           unsigned ResultMask = Op->getTransformedMask(LHS, RHS);

           if (ShufTab[ResultMask].Cost <= OpCount ||
               ShufTab[ResultMask].Cost <= ShufTab[LHS].Cost ||
               ShufTab[ResultMask].Cost <= ShufTab[RHS].Cost)
             continue;

           // Figure out the cost to evaluate this, knowing that CSE's only need
           // to be evaluated once.
           unsigned short Vals[30];
           unsigned NumVals = 0;
           EvaluateOps(LHS, Vals, NumVals);
           EvaluateOps(RHS, Vals, NumVals);

           unsigned Cost = NumVals + Op->getCost();
           if (Cost < ShufTab[ResultMask].Cost) {
             ShufTab[ResultMask].Cost = Cost;
             ShufTab[ResultMask].Op = Op;
             ShufTab[ResultMask].Arg0 = LHS;
             ShufTab[ResultMask].Arg1 = RHS;
             MadeChange = true;
           }
         }
       }
     }
   }

   std::cerr << "Finished Table has " << getNumEntered()
             << " entries established.\n";

   unsigned CostArray[10] = { 0 };

   // Compute a cost histogram.
   for (unsigned i = 0; i != 65536; ++i) {
     if (!isValidMask(i)) continue;
     if (ShufTab[i].Cost > 9)
       ++CostArray[9];
     else
       ++CostArray[ShufTab[i].Cost];
   }

   for (unsigned i = 0; i != 9; ++i)
     if (CostArray[i])
       std::cout << "// " << CostArray[i] << " entries have cost " << i << "\n";
   if (CostArray[9])
     std::cout << "// " << CostArray[9] << " entries have higher cost!\n";


   // Build up the table to emit.
   std::cout << "\n// This table is 6561*4 = 26244 bytes in size.\n";
   std::cout << "static const unsigned PerfectShuffleTable[6561+1] = {\n";

   for (unsigned i = 0; i != 0x8889; ++i) {
     if (!isValidMask(i)) continue;

     // CostSat - The cost of this operation saturated to two bits.
     unsigned CostSat = ShufTab[i].Cost;
     if (CostSat > 4) CostSat = 4;
     if (CostSat == 0) CostSat = 1;
     --CostSat;  // Cost is now between 0-3.

     unsigned OpNum = ShufTab[i].Op ? ShufTab[i].Op->OpNum : 0;
     assert(OpNum < 16 && "Too few bits to encode operation!");

     unsigned LHS = getCompressedMask(ShufTab[i].Arg0);
     unsigned RHS = getCompressedMask(ShufTab[i].Arg1);

     // Encode this as 2 bits of saturated cost, 4 bits of opcodes, 13 bits of
     // LHS, and 13 bits of RHS = 32 bits.
     unsigned Val = (CostSat << 30) | (OpNum << 26) | (LHS << 13) | RHS;

     std::cout << "  " << std::setw(10) << Val << "U, // ";
     PrintMask(i, std::cout);
     std::cout << ": Cost " << ShufTab[i].Cost;
     std::cout << " " << (ShufTab[i].Op ? ShufTab[i].Op->getName() : "copy");
     std::cout << " ";
     if (ShufTab[ShufTab[i].Arg0].Cost == 0) {
       std::cout << getZeroCostOpName(ShufTab[i].Arg0);
     } else {
       PrintMask(ShufTab[i].Arg0, std::cout);
     }

     if (ShufTab[i].Op && !ShufTab[i].Op->isOnlyLHSOperator()) {
       std::cout << ", ";
       if (ShufTab[ShufTab[i].Arg1].Cost == 0) {
         std::cout << getZeroCostOpName(ShufTab[i].Arg1);
       } else {
         PrintMask(ShufTab[i].Arg1, std::cout);
       }
     }
     std::cout << "\n";
   }
   std::cout << "  0\n};\n";

   if (0) {
     // Print out the table.
     for (unsigned i = 0; i != 0x8889; ++i) {
       if (!isValidMask(i)) continue;
       if (ShufTab[i].Cost < 1000) {
         PrintMask(i, std::cerr);
         std::cerr << " - Cost " << ShufTab[i].Cost << " - ";

         unsigned short Vals[30];
         unsigned NumVals = 0;
         EvaluateOps(i, Vals, NumVals);

         for (unsigned j = 0, e = NumVals; j != e; ++j)
           PrintOperation(j, Vals);
         std::cerr << "\n";
       }
     }
   }
 }


 #ifdef GENERATE_ALTIVEC

 ///===---------------------------------------------------------------------===//
 /// The altivec instruction definitions.  This is the altivec-specific part of
 /// this file.
 ///===---------------------------------------------------------------------===//

 // Note that the opcode numbers here must match those in the PPC backend.
 enum {
   OP_COPY = 0,   // Copy, used for things like <u,u,u,3> to say it is <0,1,2,3>
   OP_VMRGHW,
   OP_VMRGLW,
   OP_VSPLTISW0,
   OP_VSPLTISW1,
   OP_VSPLTISW2,
   OP_VSPLTISW3,
   OP_VSLDOI4,
   OP_VSLDOI8,
   OP_VSLDOI12
 };

 struct vmrghw : public Operator {
   vmrghw() : Operator(0x0415, "vmrghw", OP_VMRGHW) {}
 } the_vmrghw;

 struct vmrglw : public Operator {
   vmrglw() : Operator(0x2637, "vmrglw", OP_VMRGLW) {}
 } the_vmrglw;

 template<unsigned Elt>
 struct vspltisw : public Operator {
   vspltisw(const char *N, unsigned Opc)
     : Operator(MakeMask(Elt, Elt, Elt, Elt), N, Opc) {}
 };

 vspltisw<0> the_vspltisw0("vspltisw0", OP_VSPLTISW0);
 vspltisw<1> the_vspltisw1("vspltisw1", OP_VSPLTISW1);
 vspltisw<2> the_vspltisw2("vspltisw2", OP_VSPLTISW2);
 vspltisw<3> the_vspltisw3("vspltisw3", OP_VSPLTISW3);

 template<unsigned N>
 struct vsldoi : public Operator {
   vsldoi(const char *Name, unsigned Opc)
     : Operator(MakeMask(N&7, (N+1)&7, (N+2)&7, (N+3)&7), Name, Opc) {
   }
 };

 vsldoi<1> the_vsldoi1("vsldoi4" , OP_VSLDOI4);
 vsldoi<2> the_vsldoi2("vsldoi8" , OP_VSLDOI8);
 vsldoi<3> the_vsldoi3("vsldoi12", OP_VSLDOI12);

 #endif

 #define GENERATE_NEON

 #ifdef GENERATE_NEON
 enum {
   OP_COPY = 0,   // Copy, used for things like <u,u,u,3> to say it is <0,1,2,3>
   OP_VREV,
   OP_VDUP0,
   OP_VDUP1,
   OP_VDUP2,
   OP_VDUP3,
   OP_VEXT1,
   OP_VEXT2,
   OP_VEXT3,
   OP_VUZPL, // VUZP, left result
   OP_VUZPR, // VUZP, right result
   OP_VZIPL, // VZIP, left result
   OP_VZIPR, // VZIP, right result
   OP_VTRNL, // VTRN, left result
   OP_VTRNR  // VTRN, right result
 };

 struct vrev : public Operator {
   vrev() : Operator(0x1032, "vrev", OP_VREV) {}
 } the_vrev;

 template<unsigned Elt>
 struct vdup : public Operator {
   vdup(const char *N, unsigned Opc)
     : Operator(MakeMask(Elt, Elt, Elt, Elt), N, Opc) {}
 };

 vdup<0> the_vdup0("vdup0", OP_VDUP0);
 vdup<1> the_vdup1("vdup1", OP_VDUP1);
 vdup<2> the_vdup2("vdup2", OP_VDUP2);
 vdup<3> the_vdup3("vdup3", OP_VDUP3);

 template<unsigned N>
 struct vext : public Operator {
   vext(const char *Name, unsigned Opc)
     : Operator(MakeMask(N&7, (N+1)&7, (N+2)&7, (N+3)&7), Name, Opc) {
   }
 };

 vext<1> the_vext1("vext1", OP_VEXT1);
 vext<2> the_vext2("vext2", OP_VEXT2);
 vext<3> the_vext3("vext3", OP_VEXT3);

 struct vuzpl : public Operator {
   vuzpl() : Operator(0x0246, "vuzpl", OP_VUZPL, 2) {}
 } the_vuzpl;

 struct vuzpr : public Operator {
   vuzpr() : Operator(0x1357, "vuzpr", OP_VUZPR, 2) {}
 } the_vuzpr;

 struct vzipl : public Operator {
   vzipl() : Operator(0x0415, "vzipl", OP_VZIPL, 2) {}
 } the_vzipl;

 struct vzipr : public Operator {
   vzipr() : Operator(0x2637, "vzipr", OP_VZIPR, 2) {}
 } the_vzipr;

 struct vtrnl : public Operator {
   vtrnl() : Operator(0x0426, "vtrnl", OP_VTRNL, 2) {}
 } the_vtrnl;

 struct vtrnr : public Operator {
   vtrnr() : Operator(0x1537, "vtrnr", OP_VTRNR, 2) {}
 } the_vtrnr;

 #endif
	//===-- PerfectShuffle.cpp - Perfect Shuffle Generator --------------------===//
	//
	// The LLVM Compiler Infrastructure
	//
	// This file is distributed under the University of Illinois Open Source
	// License. See LICENSE.TXT for details.
	//
	//===----------------------------------------------------------------------===//
	//
	// This file computes an optimal sequence of instructions for doing all shuffles
	// of two 4-element vectors. With a release build and when configured to emit
	// an altivec instruction table, this takes about 30s to run on a 2.7Ghz
	// PowerPC G5.
	//
	//===----------------------------------------------------------------------===//

	#include <cassert>
	#include <cstdlib>
	#include <iomanip>
	#include <iostream>
	#include <vector>
	struct Operator;

	// Masks are 4-nibble hex numbers. Values 0-7 in any nibble means that it takes
	// an element from that value of the input vectors. A value of 8 means the
	// entry is undefined.

	// Mask manipulation functions.
	static inline unsigned short MakeMask(unsigned V0, unsigned V1,
	unsigned V2, unsigned V3) {
	return (V0 << (34)) \| (V1 << (24)) \| (V2 << (14)) \| (V3 << (04));
	}

	/// getMaskElt - Return element N of the specified mask.
	static unsigned getMaskElt(unsigned Mask, unsigned Elt) {
	return (Mask >> ((3-Elt)*4)) & 0xF;
	}

	static unsigned setMaskElt(unsigned Mask, unsigned Elt, unsigned NewVal) {
	unsigned FieldShift = ((3-Elt)*4);
	return (Mask & ~(0xF << FieldShift)) \| (NewVal << FieldShift);
	}

	// Reject elements where the values are 9-15.
	static bool isValidMask(unsigned short Mask) {
	unsigned short UndefBits = Mask & 0x8888;
	return (Mask & ((UndefBits >> 1)\|(UndefBits>>2)\|(UndefBits>>3))) == 0;
	}

	/// hasUndefElements - Return true if any of the elements in the mask are undefs
	///
	static bool hasUndefElements(unsigned short Mask) {
	return (Mask & 0x8888) != 0;
	}

	/// isOnlyLHSMask - Return true if this mask only refers to its LHS, not
	/// including undef values..
	static bool isOnlyLHSMask(unsigned short Mask) {
	return (Mask & 0x4444) == 0;
	}

	/// getLHSOnlyMask - Given a mask that refers to its LHS and RHS, modify it to
	/// refer to the LHS only (for when one argument value is passed into the same
	/// function twice).
	#if 0
	static unsigned short getLHSOnlyMask(unsigned short Mask) {
	return Mask & 0xBBBB; // Keep only LHS and Undefs.
	}
	#endif

	/// getCompressedMask - Turn a 16-bit uncompressed mask (where each elt uses 4
	/// bits) into a compressed 13-bit mask, where each elt is multiplied by 9.
	static unsigned getCompressedMask(unsigned short Mask) {
	return getMaskElt(Mask, 0)999 + getMaskElt(Mask, 1)9*9 +
	getMaskElt(Mask, 2)*9 + getMaskElt(Mask, 3);
	}

	static void PrintMask(unsigned i, std::ostream &OS) {
	OS << "<" << (char)(getMaskElt(i, 0) == 8 ? 'u' : ('0'+getMaskElt(i, 0)))
	<< "," << (char)(getMaskElt(i, 1) == 8 ? 'u' : ('0'+getMaskElt(i, 1)))
	<< "," << (char)(getMaskElt(i, 2) == 8 ? 'u' : ('0'+getMaskElt(i, 2)))
	<< "," << (char)(getMaskElt(i, 3) == 8 ? 'u' : ('0'+getMaskElt(i, 3)))
	<< ">";
	}

	/// ShuffleVal - This represents a shufflevector operation.
	struct ShuffleVal {
	Operator *Op; // The Operation used to generate this value.
	unsigned Cost; // Number of instrs used to generate this value.
	unsigned short Arg0, Arg1; // Input operands for this value.

	ShuffleVal() : Cost(1000000) {}
	};


	/// ShufTab - This is the actual shuffle table that we are trying to generate.
	///
	static ShuffleVal ShufTab[65536];

	/// TheOperators - All of the operators that this target supports.
	static std::vector<Operator*> TheOperators;

	/// Operator - This is a vector operation that is available for use.
	struct Operator {
	const char *Name;
	unsigned short ShuffleMask;
	unsigned short OpNum;
	unsigned Cost;

	Operator(unsigned short shufflemask, const char *name, unsigned opnum,
	unsigned cost = 1)
	: Name(name), ShuffleMask(shufflemask), OpNum(opnum),Cost(cost) {
	TheOperators.push_back(this);
	}
	~Operator() {
	assert(TheOperators.back() == this);
	TheOperators.pop_back();
	}

	bool isOnlyLHSOperator() const {
	return isOnlyLHSMask(ShuffleMask);
	}

	const char *getName() const { return Name; }
	unsigned getCost() const { return Cost; }

	unsigned short getTransformedMask(unsigned short LHSMask, unsigned RHSMask) {
	// Extract the elements from LHSMask and RHSMask, as appropriate.
	unsigned Result = 0;
	for (unsigned i = 0; i != 4; ++i) {
	unsigned SrcElt = (ShuffleMask >> (4*i)) & 0xF;
	unsigned ResElt;
	if (SrcElt < 4)
	ResElt = getMaskElt(LHSMask, SrcElt);
	else if (SrcElt < 8)
	ResElt = getMaskElt(RHSMask, SrcElt-4);
	else {
	assert(SrcElt == 8 && "Bad src elt!");
	ResElt = 8;
	}
	Result \|= ResElt << (4*i);
	}
	return Result;
	}
	};

	static const char *getZeroCostOpName(unsigned short Op) {
	if (ShufTab[Op].Arg0 == 0x0123)
	return "LHS";
	else if (ShufTab[Op].Arg0 == 0x4567)
	return "RHS";
	else {
	assert(0 && "bad zero cost operation");
	abort();
	}
	}

	static void PrintOperation(unsigned ValNo, unsigned short Vals[]) {
	unsigned short ThisOp = Vals[ValNo];
	std::cerr << "t" << ValNo;
	PrintMask(ThisOp, std::cerr);
	std::cerr << " = " << ShufTab[ThisOp].Op->getName() << "(";

	if (ShufTab[ShufTab[ThisOp].Arg0].Cost == 0) {
	std::cerr << getZeroCostOpName(ShufTab[ThisOp].Arg0);
	PrintMask(ShufTab[ThisOp].Arg0, std::cerr);
	} else {
	// Figure out what tmp # it is.
	for (unsigned i = 0; ; ++i)
	if (Vals[i] == ShufTab[ThisOp].Arg0) {
	std::cerr << "t" << i;
	break;
	}
	}

	if (!ShufTab[Vals[ValNo]].Op->isOnlyLHSOperator()) {
	std::cerr << ", ";
	if (ShufTab[ShufTab[ThisOp].Arg1].Cost == 0) {
	std::cerr << getZeroCostOpName(ShufTab[ThisOp].Arg1);
	PrintMask(ShufTab[ThisOp].Arg1, std::cerr);
	} else {
	// Figure out what tmp # it is.
	for (unsigned i = 0; ; ++i)
	if (Vals[i] == ShufTab[ThisOp].Arg1) {
	std::cerr << "t" << i;
	break;
	}
	}
	}
	std::cerr << ") ";
	}

	static unsigned getNumEntered() {
	unsigned Count = 0;
	for (unsigned i = 0; i != 65536; ++i)
	Count += ShufTab[i].Cost < 100;
	return Count;
	}

	static void EvaluateOps(unsigned short Elt, unsigned short Vals[],
	unsigned &NumVals) {
	if (ShufTab[Elt].Cost == 0) return;

	// If this value has already been evaluated, it is free. FIXME: match undefs.
	for (unsigned i = 0, e = NumVals; i != e; ++i)
	if (Vals[i] == Elt) return;

	// Otherwise, get the operands of the value, then add it.
	unsigned Arg0 = ShufTab[Elt].Arg0, Arg1 = ShufTab[Elt].Arg1;
	if (ShufTab[Arg0].Cost)
	EvaluateOps(Arg0, Vals, NumVals);
	if (Arg0 != Arg1 && ShufTab[Arg1].Cost)
	EvaluateOps(Arg1, Vals, NumVals);

	Vals[NumVals++] = Elt;
	}


	int main() {
	// Seed the table with accesses to the LHS and RHS.
	ShufTab[0x0123].Cost = 0;
	ShufTab[0x0123].Op = nullptr;
	ShufTab[0x0123].Arg0 = 0x0123;
	ShufTab[0x4567].Cost = 0;
	ShufTab[0x4567].Op = nullptr;
	ShufTab[0x4567].Arg0 = 0x4567;

	// Seed the first-level of shuffles, shuffles whose inputs are the input to
	// the vectorshuffle operation.
	bool MadeChange = true;
	unsigned OpCount = 0;
	while (MadeChange) {
	MadeChange = false;
	++OpCount;
	std::cerr << "Starting iteration #" << OpCount << " with "
	<< getNumEntered() << " entries established.\n";

	// Scan the table for two reasons: First, compute the maximum cost of any
	// operation left in the table. Second, make sure that values with undefs
	// have the cheapest alternative that they match.
	unsigned MaxCost = ShufTab[0].Cost;
	for (unsigned i = 1; i != 0x8889; ++i) {
	if (!isValidMask(i)) continue;
	if (ShufTab[i].Cost > MaxCost)
	MaxCost = ShufTab[i].Cost;

	// If this value has an undef, make it be computed the cheapest possible
	// way of any of the things that it matches.
	if (hasUndefElements(i)) {
	// This code is a little bit tricky, so here's the idea: consider some
	// permutation, like 7u4u. To compute the lowest cost for 7u4u, we
	// need to take the minimum cost of all of 7[0-8]4[0-8], 81 entries. If
	// there are 3 undefs, the number rises to 729 entries we have to scan,
	// and for the 4 undef case, we have to scan the whole table.
	//
	// Instead of doing this huge amount of scanning, we process the table
	// entries in order, and use the fact that 'u' is 8, larger than any
	// valid index. Given an entry like 7u4u then, we only need to scan
	// 7[0-7]4u - 8 entries. We can get away with this, because we already
	// know that each of 704u, 714u, 724u, etc contain the minimum value of
	// all of the 704[0-8], 714[0-8] and 724[0-8] entries respectively.
	unsigned UndefIdx;
	if (i & 0x8000)
	UndefIdx = 0;
	else if (i & 0x0800)
	UndefIdx = 1;
	else if (i & 0x0080)
	UndefIdx = 2;
	else if (i & 0x0008)
	UndefIdx = 3;
	else
	abort();

	unsigned MinVal = i;
	unsigned MinCost = ShufTab[i].Cost;

	// Scan the 8 entries.
	for (unsigned j = 0; j != 8; ++j) {
	unsigned NewElt = setMaskElt(i, UndefIdx, j);
	if (ShufTab[NewElt].Cost < MinCost) {
	MinCost = ShufTab[NewElt].Cost;
	MinVal = NewElt;
	}
	}

	// If we found something cheaper than what was here before, use it.
	if (i != MinVal) {
	MadeChange = true;
	ShufTab[i] = ShufTab[MinVal];
	}
	}
	}

	for (unsigned LHS = 0; LHS != 0x8889; ++LHS) {
	if (!isValidMask(LHS)) continue;
	if (ShufTab[LHS].Cost > 1000) continue;

	// If nothing involving this operand could possibly be cheaper than what
	// we already have, don't consider it.
	if (ShufTab[LHS].Cost + 1 >= MaxCost)
	continue;

	for (unsigned opnum = 0, e = TheOperators.size(); opnum != e; ++opnum) {
	Operator *Op = TheOperators[opnum];

	// Evaluate op(LHS,LHS)
	unsigned ResultMask = Op->getTransformedMask(LHS, LHS);

	unsigned Cost = ShufTab[LHS].Cost + Op->getCost();
	if (Cost < ShufTab[ResultMask].Cost) {
	ShufTab[ResultMask].Cost = Cost;
	ShufTab[ResultMask].Op = Op;
	ShufTab[ResultMask].Arg0 = LHS;
	ShufTab[ResultMask].Arg1 = LHS;
	MadeChange = true;
	}

	// If this is a two input instruction, include the op(x,y) cases. If
	// this is a one input instruction, skip this.
	if (Op->isOnlyLHSOperator()) continue;

	for (unsigned RHS = 0; RHS != 0x8889; ++RHS) {
	if (!isValidMask(RHS)) continue;
	if (ShufTab[RHS].Cost > 1000) continue;

	// If nothing involving this operand could possibly be cheaper than
	// what we already have, don't consider it.
	if (ShufTab[RHS].Cost + 1 >= MaxCost)
	continue;


	// Evaluate op(LHS,RHS)
	unsigned ResultMask = Op->getTransformedMask(LHS, RHS);

	if (ShufTab[ResultMask].Cost <= OpCount \|\|
	ShufTab[ResultMask].Cost <= ShufTab[LHS].Cost \|\|
	ShufTab[ResultMask].Cost <= ShufTab[RHS].Cost)
	continue;

	// Figure out the cost to evaluate this, knowing that CSE's only need
	// to be evaluated once.
	unsigned short Vals[30];
	unsigned NumVals = 0;
	EvaluateOps(LHS, Vals, NumVals);
	EvaluateOps(RHS, Vals, NumVals);

	unsigned Cost = NumVals + Op->getCost();
	if (Cost < ShufTab[ResultMask].Cost) {
	ShufTab[ResultMask].Cost = Cost;
	ShufTab[ResultMask].Op = Op;
	ShufTab[ResultMask].Arg0 = LHS;
	ShufTab[ResultMask].Arg1 = RHS;
	MadeChange = true;
	}
	}
	}
	}
	}

	std::cerr << "Finished Table has " << getNumEntered()
	<< " entries established.\n";

	unsigned CostArray[10] = { 0 };

	// Compute a cost histogram.
	for (unsigned i = 0; i != 65536; ++i) {
	if (!isValidMask(i)) continue;
	if (ShufTab[i].Cost > 9)
	++CostArray[9];
	else
	++CostArray[ShufTab[i].Cost];
	}

	for (unsigned i = 0; i != 9; ++i)
	if (CostArray[i])
	std::cout << "// " << CostArray[i] << " entries have cost " << i << "\n";
	if (CostArray[9])
	std::cout << "// " << CostArray[9] << " entries have higher cost!\n";


	// Build up the table to emit.
	std::cout << "\n// This table is 6561*4 = 26244 bytes in size.\n";
	std::cout << "static const unsigned PerfectShuffleTable[6561+1] = {\n";

	for (unsigned i = 0; i != 0x8889; ++i) {
	if (!isValidMask(i)) continue;

	// CostSat - The cost of this operation saturated to two bits.
	unsigned CostSat = ShufTab[i].Cost;
	if (CostSat > 4) CostSat = 4;
	if (CostSat == 0) CostSat = 1;
	--CostSat; // Cost is now between 0-3.

	unsigned OpNum = ShufTab[i].Op ? ShufTab[i].Op->OpNum : 0;
	assert(OpNum < 16 && "Too few bits to encode operation!");

	unsigned LHS = getCompressedMask(ShufTab[i].Arg0);
	unsigned RHS = getCompressedMask(ShufTab[i].Arg1);

	// Encode this as 2 bits of saturated cost, 4 bits of opcodes, 13 bits of
	// LHS, and 13 bits of RHS = 32 bits.
	unsigned Val = (CostSat << 30) \| (OpNum << 26) \| (LHS << 13) \| RHS;

	std::cout << " " << std::setw(10) << Val << "U, // ";
	PrintMask(i, std::cout);
	std::cout << ": Cost " << ShufTab[i].Cost;
	std::cout << " " << (ShufTab[i].Op ? ShufTab[i].Op->getName() : "copy");
	std::cout << " ";
	if (ShufTab[ShufTab[i].Arg0].Cost == 0) {
	std::cout << getZeroCostOpName(ShufTab[i].Arg0);
	} else {
	PrintMask(ShufTab[i].Arg0, std::cout);
	}

	if (ShufTab[i].Op && !ShufTab[i].Op->isOnlyLHSOperator()) {
	std::cout << ", ";
	if (ShufTab[ShufTab[i].Arg1].Cost == 0) {
	std::cout << getZeroCostOpName(ShufTab[i].Arg1);
	} else {
	PrintMask(ShufTab[i].Arg1, std::cout);
	}
	}
	std::cout << "\n";
	}
	std::cout << " 0\n};\n";

	if (0) {
	// Print out the table.
	for (unsigned i = 0; i != 0x8889; ++i) {
	if (!isValidMask(i)) continue;
	if (ShufTab[i].Cost < 1000) {
	PrintMask(i, std::cerr);
	std::cerr << " - Cost " << ShufTab[i].Cost << " - ";

	unsigned short Vals[30];
	unsigned NumVals = 0;
	EvaluateOps(i, Vals, NumVals);

	for (unsigned j = 0, e = NumVals; j != e; ++j)
	PrintOperation(j, Vals);
	std::cerr << "\n";
	}
	}
	}
	}


	#ifdef GENERATE_ALTIVEC

	///===---------------------------------------------------------------------===//
	/// The altivec instruction definitions. This is the altivec-specific part of
	/// this file.
	///===---------------------------------------------------------------------===//

	// Note that the opcode numbers here must match those in the PPC backend.
	enum {
	OP_COPY = 0, // Copy, used for things like <u,u,u,3> to say it is <0,1,2,3>
	OP_VMRGHW,
	OP_VMRGLW,
	OP_VSPLTISW0,
	OP_VSPLTISW1,
	OP_VSPLTISW2,
	OP_VSPLTISW3,
	OP_VSLDOI4,
	OP_VSLDOI8,
	OP_VSLDOI12
	};

	struct vmrghw : public Operator {
	vmrghw() : Operator(0x0415, "vmrghw", OP_VMRGHW) {}
	} the_vmrghw;

	struct vmrglw : public Operator {
	vmrglw() : Operator(0x2637, "vmrglw", OP_VMRGLW) {}
	} the_vmrglw;

	template<unsigned Elt>
	struct vspltisw : public Operator {
	vspltisw(const char *N, unsigned Opc)
	: Operator(MakeMask(Elt, Elt, Elt, Elt), N, Opc) {}
	};

	vspltisw<0> the_vspltisw0("vspltisw0", OP_VSPLTISW0);
	vspltisw<1> the_vspltisw1("vspltisw1", OP_VSPLTISW1);
	vspltisw<2> the_vspltisw2("vspltisw2", OP_VSPLTISW2);
	vspltisw<3> the_vspltisw3("vspltisw3", OP_VSPLTISW3);

	template<unsigned N>
	struct vsldoi : public Operator {
	vsldoi(const char *Name, unsigned Opc)
	: Operator(MakeMask(N&7, (N+1)&7, (N+2)&7, (N+3)&7), Name, Opc) {
	}
	};

	vsldoi<1> the_vsldoi1("vsldoi4" , OP_VSLDOI4);
	vsldoi<2> the_vsldoi2("vsldoi8" , OP_VSLDOI8);
	vsldoi<3> the_vsldoi3("vsldoi12", OP_VSLDOI12);

	#endif

	#define GENERATE_NEON

	#ifdef GENERATE_NEON
	enum {
	OP_COPY = 0, // Copy, used for things like <u,u,u,3> to say it is <0,1,2,3>
	OP_VREV,
	OP_VDUP0,
	OP_VDUP1,
	OP_VDUP2,
	OP_VDUP3,
	OP_VEXT1,
	OP_VEXT2,
	OP_VEXT3,
	OP_VUZPL, // VUZP, left result
	OP_VUZPR, // VUZP, right result
	OP_VZIPL, // VZIP, left result
	OP_VZIPR, // VZIP, right result
	OP_VTRNL, // VTRN, left result
	OP_VTRNR // VTRN, right result
	};

	struct vrev : public Operator {
	vrev() : Operator(0x1032, "vrev", OP_VREV) {}
	} the_vrev;

	template<unsigned Elt>
	struct vdup : public Operator {
	vdup(const char *N, unsigned Opc)
	: Operator(MakeMask(Elt, Elt, Elt, Elt), N, Opc) {}
	};

	vdup<0> the_vdup0("vdup0", OP_VDUP0);
	vdup<1> the_vdup1("vdup1", OP_VDUP1);
	vdup<2> the_vdup2("vdup2", OP_VDUP2);
	vdup<3> the_vdup3("vdup3", OP_VDUP3);

	template<unsigned N>
	struct vext : public Operator {
	vext(const char *Name, unsigned Opc)
	: Operator(MakeMask(N&7, (N+1)&7, (N+2)&7, (N+3)&7), Name, Opc) {
	}
	};

	vext<1> the_vext1("vext1", OP_VEXT1);
	vext<2> the_vext2("vext2", OP_VEXT2);
	vext<3> the_vext3("vext3", OP_VEXT3);

	struct vuzpl : public Operator {
	vuzpl() : Operator(0x0246, "vuzpl", OP_VUZPL, 2) {}
	} the_vuzpl;

	struct vuzpr : public Operator {
	vuzpr() : Operator(0x1357, "vuzpr", OP_VUZPR, 2) {}
	} the_vuzpr;

	struct vzipl : public Operator {
	vzipl() : Operator(0x0415, "vzipl", OP_VZIPL, 2) {}
	} the_vzipl;

	struct vzipr : public Operator {
	vzipr() : Operator(0x2637, "vzipr", OP_VZIPR, 2) {}
	} the_vzipr;

	struct vtrnl : public Operator {
	vtrnl() : Operator(0x0426, "vtrnl", OP_VTRNL, 2) {}
	} the_vtrnl;

	struct vtrnr : public Operator {
	vtrnr() : Operator(0x1537, "vtrnr", OP_VTRNR, 2) {}
	} the_vtrnr;

	#endif