third_party/subzero/crosstest/test_icmp_main.cpp - SwiftShader - Git at Google

 //===- subzero/crosstest/test_icmp_main.cpp - Driver for tests. -----------===//
 //
 //                        The Subzero Code Generator
 //
 // This file is distributed under the University of Illinois Open Source
 // License. See LICENSE.TXT for details.
 //
 //===----------------------------------------------------------------------===//
 //
 // Driver for cross testing the icmp bitcode instruction
 //
 //===----------------------------------------------------------------------===//

 /* crosstest.py --test=test_icmp.cpp --test=test_icmp_i1vec.ll \
    --driver=test_icmp_main.cpp --prefix=Subzero_ --output=test_icmp */

 #include <climits> // CHAR_BIT
 #include <cstring> // memcmp, memset
 #include <stdint.h>
 #include <iostream>

 // Include test_icmp.h twice - once normally, and once within the
 // Subzero_ namespace, corresponding to the llc and Subzero translated
 // object files, respectively.
 #include "test_icmp.h"

 namespace Subzero_ {
 #include "test_icmp.h"
 }

 #include "insertelement.h"
 #include "xdefs.h"

 volatile unsigned Values[] = {
     0x0,        0x1,        0x7ffffffe, 0x7fffffff, 0x80000000, 0x80000001,
     0xfffffffe, 0xffffffff, 0x7e,       0x7f,       0x80,       0x81,
     0xfe,       0xff,       0x100,      0x101,      0x7ffe,     0x7fff,
     0x8000,     0x8001,     0xfffe,     0xffff,     0x10000,    0x10001,
 };
 const static size_t NumValues = sizeof(Values) / sizeof(*Values);

 template <typename TypeUnsigned, typename TypeSigned>
 void testsInt(size_t &TotalTests, size_t &Passes, size_t &Failures) {
   typedef bool (*FuncTypeUnsigned)(TypeUnsigned, TypeUnsigned);
   typedef bool (*FuncTypeSigned)(TypeSigned, TypeSigned);
   static struct {
     const char *Name;
     FuncTypeUnsigned FuncLlc;
     FuncTypeUnsigned FuncSz;
   } Funcs[] = {
 #define X(cmp, op)                                                             \
   {                                                                            \
     STR(cmp), (FuncTypeUnsigned)icmp##cmp,                                     \
         (FuncTypeUnsigned)Subzero_::icmp##cmp                                  \
   }                                                                            \
   ,
       ICMP_U_TABLE
 #undef X
 #define X(cmp, op)                                                             \
   {                                                                            \
     STR(cmp), (FuncTypeUnsigned)(FuncTypeSigned)icmp##cmp,                     \
         (FuncTypeUnsigned)(FuncTypeSigned)Subzero_::icmp##cmp                  \
   }                                                                            \
   ,
           ICMP_S_TABLE
 #undef X
   };
   const static size_t NumFuncs = sizeof(Funcs) / sizeof(*Funcs);

   if (sizeof(TypeUnsigned) <= sizeof(uint32_t)) {
     // This is the "normal" version of the loop nest, for 32-bit or
     // narrower types.
     for (size_t f = 0; f < NumFuncs; ++f) {
       for (size_t i = 0; i < NumValues; ++i) {
         for (size_t j = 0; j < NumValues; ++j) {
           TypeUnsigned Value1 = Values[i];
           TypeUnsigned Value2 = Values[j];
           ++TotalTests;
           bool ResultSz = Funcs[f].FuncSz(Value1, Value2);
           bool ResultLlc = Funcs[f].FuncLlc(Value1, Value2);
           if (ResultSz == ResultLlc) {
             ++Passes;
           } else {
             ++Failures;
             std::cout << "icmp" << Funcs[f].Name
                       << (CHAR_BIT * sizeof(TypeUnsigned)) << "(" << Value1
                       << ", " << Value2 << "): sz=" << ResultSz
                       << " llc=" << ResultLlc << "\n";
           }
         }
       }
     }
   } else {
     // This is the 64-bit version.  Test values are synthesized from
     // the 32-bit values in Values[].
     for (size_t f = 0; f < NumFuncs; ++f) {
       for (size_t iLo = 0; iLo < NumValues; ++iLo) {
         for (size_t iHi = 0; iHi < NumValues; ++iHi) {
           for (size_t jLo = 0; jLo < NumValues; ++jLo) {
             for (size_t jHi = 0; jHi < NumValues; ++jHi) {
               TypeUnsigned Value1 =
                   (((TypeUnsigned)Values[iHi]) << 32) + Values[iLo];
               TypeUnsigned Value2 =
                   (((TypeUnsigned)Values[jHi]) << 32) + Values[jLo];
               ++TotalTests;
               bool ResultSz = Funcs[f].FuncSz(Value1, Value2);
               bool ResultLlc = Funcs[f].FuncLlc(Value1, Value2);
               if (ResultSz == ResultLlc) {
                 ++Passes;
               } else {
                 ++Failures;
                 std::cout << "icmp" << Funcs[f].Name
                           << (CHAR_BIT * sizeof(TypeUnsigned)) << "(" << Value1
                           << ", " << Value2 << "): sz=" << ResultSz
                           << " llc=" << ResultLlc << "\n";
               }
             }
           }
         }
       }
     }
   }
 }

 template <typename TypeUnsigned, typename TypeSigned>
 void testsIntWithZero(size_t &TotalTests, size_t &Passes, size_t &Failures) {
   typedef bool (*FuncTypeUnsigned)(TypeUnsigned);
   typedef bool (*FuncTypeSigned)(TypeSigned);
   static struct {
     const char *Name;
     FuncTypeUnsigned FuncLlc;
     FuncTypeUnsigned FuncSz;
   } Funcs[] = {
 #define X(cmp, op)                                                             \
   {                                                                            \
     STR(cmp), (FuncTypeUnsigned)icmp_zero##cmp,                                \
         (FuncTypeUnsigned)Subzero_::icmp_zero##cmp                             \
   }                                                                            \
   ,
       ICMP_U_TABLE
 #undef X
 #define X(cmp, op)                                                             \
   {                                                                            \
     STR(cmp), (FuncTypeUnsigned)(FuncTypeSigned)icmp_zero##cmp,                \
         (FuncTypeUnsigned)(FuncTypeSigned)Subzero_::icmp_zero##cmp             \
   }                                                                            \
   ,
           ICMP_S_TABLE
 #undef X
   };
   const static size_t NumFuncs = sizeof(Funcs) / sizeof(*Funcs);

   if (sizeof(TypeUnsigned) <= sizeof(uint32_t)) {
     // This is the "normal" version of the loop nest, for 32-bit or
     // narrower types.
     for (size_t f = 0; f < NumFuncs; ++f) {
       for (size_t i = 0; i < NumValues; ++i) {
         TypeUnsigned Value = Values[i];
         ++TotalTests;
         bool ResultSz = Funcs[f].FuncSz(Value);
         bool ResultLlc = Funcs[f].FuncLlc(Value);
         if (ResultSz == ResultLlc) {
           ++Passes;
         } else {
           ++Failures;
           std::cout << "icmp" << Funcs[f].Name
                     << (CHAR_BIT * sizeof(TypeUnsigned)) << "(" << Value
                     << "): sz=" << ResultSz << " llc=" << ResultLlc << "\n";
         }
       }
     }
   } else {
     // This is the 64-bit version.  Test values are synthesized from
     // the 32-bit values in Values[].
     for (size_t f = 0; f < NumFuncs; ++f) {
       for (size_t iLo = 0; iLo < NumValues; ++iLo) {
         for (size_t iHi = 0; iHi < NumValues; ++iHi) {
           TypeUnsigned Value =
               (((TypeUnsigned)Values[iHi]) << 32) + Values[iLo];
           ++TotalTests;
           bool ResultSz = Funcs[f].FuncSz(Value);
           bool ResultLlc = Funcs[f].FuncLlc(Value);
           if (ResultSz == ResultLlc) {
             ++Passes;
           } else {
             ++Failures;
             std::cout << "icmp" << Funcs[f].Name
                       << (CHAR_BIT * sizeof(TypeUnsigned)) << "(" << Value
                       << "): sz=" << ResultSz << " llc=" << ResultLlc << "\n";
           }
         }
       }
     }
   }
 }

 const static size_t MaxTestsPerFunc = 100000;

 template <typename TypeUnsignedLabel, typename TypeSignedLabel>
 void testsVecInt(size_t &TotalTests, size_t &Passes, size_t &Failures) {
   typedef typename Vectors<TypeUnsignedLabel>::Ty TypeUnsigned;
   typedef typename Vectors<TypeSignedLabel>::Ty TypeSigned;
   typedef typename Vectors<TypeUnsignedLabel>::ElementTy ElementTypeUnsigned;
   typedef typename Vectors<TypeSignedLabel>::ElementTy ElementTypeSigned;
   typedef TypeUnsigned (*FuncTypeUnsigned)(TypeUnsigned, TypeUnsigned);
   typedef TypeSigned (*FuncTypeSigned)(TypeSigned, TypeSigned);
   static struct {
     const char *Name;
     FuncTypeUnsigned FuncLlc;
     FuncTypeUnsigned FuncSz;
   } Funcs[] = {
 #define X(cmp, op)                                                             \
   {                                                                            \
     STR(cmp), (FuncTypeUnsigned)icmp##cmp,                                     \
         (FuncTypeUnsigned)Subzero_::icmp##cmp                                  \
   }                                                                            \
   ,
       ICMP_U_TABLE
 #undef X
 #define X(cmp, op)                                                             \
   {                                                                            \
     STR(cmp), (FuncTypeUnsigned)(FuncTypeSigned)icmp##cmp,                     \
         (FuncTypeUnsigned)(FuncTypeSigned)Subzero_::icmp##cmp                  \
   }                                                                            \
   ,
           ICMP_S_TABLE
 #undef X
   };
   const static size_t NumFuncs = sizeof(Funcs) / sizeof(*Funcs);
   const static size_t NumElementsInType = Vectors<TypeUnsigned>::NumElements;
   for (size_t f = 0; f < NumFuncs; ++f) {
     PRNG Index;
     for (size_t i = 0; i < MaxTestsPerFunc; ++i) {
       // Initialize the test vectors.
       TypeUnsigned Value1, Value2;
       for (size_t j = 0; j < NumElementsInType; ++j) {
         setElement(Value1, j, Values[Index() % NumValues]);
         setElement(Value2, j, Values[Index() % NumValues]);
       }
       // Perform the test.
       TypeUnsigned ResultSz = Funcs[f].FuncSz(Value1, Value2);
       TypeUnsigned ResultLlc = Funcs[f].FuncLlc(Value1, Value2);
       ++TotalTests;
       if (!memcmp(&ResultSz, &ResultLlc, sizeof(ResultSz))) {
         ++Passes;
       } else {
         ++Failures;
         std::cout << "test" << Funcs[f].Name
                   << Vectors<TypeUnsignedLabel>::TypeName << "("
                   << vectAsString<TypeUnsignedLabel>(Value1) << ","
                   << vectAsString<TypeUnsignedLabel>(Value2)
                   << "): sz=" << vectAsString<TypeUnsignedLabel>(ResultSz)
                   << " llc=" << vectAsString<TypeUnsignedLabel>(ResultLlc)
                   << "\n";
       }
     }
   }
 }

 // Return true on wraparound
 template <typename T>
 bool __attribute__((noinline))
 incrementI1Vector(typename Vectors<T>::Ty &Vect) {
   size_t Pos = 0;
   const static size_t NumElements = Vectors<T>::NumElements;
   for (Pos = 0; Pos < NumElements; ++Pos) {
     if (Vect[Pos] == 0) {
       Vect[Pos] = 1;
       break;
     }
     Vect[Pos] = 0;
   }
   return (Pos == NumElements);
 }

 template <typename T>
 void testsVecI1(size_t &TotalTests, size_t &Passes, size_t &Failures) {
   typedef typename Vectors<T>::Ty Ty;
   typedef Ty (*FuncType)(Ty, Ty);
   static struct {
     const char *Name;
     FuncType FuncLlc;
     FuncType FuncSz;
   } Funcs[] = {
 #define X(cmp, op)                                                             \
   { STR(cmp), (FuncType)icmpi1##cmp, (FuncType)Subzero_::icmpi1##cmp }         \
   ,
       ICMP_U_TABLE ICMP_S_TABLE};
   const static size_t NumFuncs = sizeof(Funcs) / sizeof(*Funcs);
   const static size_t NumElements = Vectors<T>::NumElements;
   const static size_t MAX_NUMBER_OF_ELEMENTS_FOR_EXHAUSTIVE_TESTING = 8;

   // Check if the type is small enough to try all possible input pairs.
   if (NumElements <= MAX_NUMBER_OF_ELEMENTS_FOR_EXHAUSTIVE_TESTING) {
     for (size_t f = 0; f < NumFuncs; ++f) {
       Ty Value1, Value2;
       memset(&Value1, 0, sizeof(Value1));
       for (bool IsValue1Done = false; !IsValue1Done;
            IsValue1Done = incrementI1Vector<T>(Value1)) {
         memset(&Value2, 0, sizeof(Value2));
         for (bool IsValue2Done = false; !IsValue2Done;
              IsValue2Done = incrementI1Vector<T>(Value2)) {
           Ty ResultSz = Funcs[f].FuncSz(Value1, Value2);
           Ty ResultLlc = Funcs[f].FuncLlc(Value1, Value2);
           ++TotalTests;
           if (!memcmp(&ResultSz, &ResultLlc, sizeof(ResultSz))) {
             ++Passes;
           } else {
             ++Failures;
             std::cout << "test" << Funcs[f].Name << Vectors<T>::TypeName << "("
                       << vectAsString<T>(Value1) << ","
                       << vectAsString<T>(Value2)
                       << "): sz=" << vectAsString<T>(ResultSz)
                       << " llc=" << vectAsString<T>(ResultLlc) << "\n";
           }
         }
       }
     }
   } else {
     for (size_t f = 0; f < NumFuncs; ++f) {
       PRNG Index;
       for (size_t i = 0; i < MaxTestsPerFunc; ++i) {
         Ty Value1, Value2;
         // Initialize the test vectors.
         for (size_t j = 0; j < NumElements; ++j) {
           setElement(Value1, j, Index() % 2);
           setElement(Value2, j, Index() % 2);
         }
         // Perform the test.
         Ty ResultSz = Funcs[f].FuncSz(Value1, Value2);
         Ty ResultLlc = Funcs[f].FuncLlc(Value1, Value2);
         ++TotalTests;
         if (!memcmp(&ResultSz, &ResultLlc, sizeof(ResultSz))) {
           ++Passes;
         } else {
           ++Failures;
           std::cout << "test" << Funcs[f].Name << Vectors<T>::TypeName << "("
                     << vectAsString<T>(Value1) << "," << vectAsString<T>(Value2)
                     << "): sz=" << vectAsString<T>(ResultSz)
                     << " llc=" << vectAsString<T>(ResultLlc) << "\n";
         }
       }
     }
   }
 }

 int main(int argc, char *argv[]) {
   size_t TotalTests = 0;
   size_t Passes = 0;
   size_t Failures = 0;

   testsInt<uint8_t, myint8_t>(TotalTests, Passes, Failures);
   testsInt<uint16_t, int16_t>(TotalTests, Passes, Failures);
   testsInt<uint32_t, int32_t>(TotalTests, Passes, Failures);
   testsInt<uint64, int64>(TotalTests, Passes, Failures);
   testsIntWithZero<uint8_t, myint8_t>(TotalTests, Passes, Failures);
   testsIntWithZero<uint16_t, int16_t>(TotalTests, Passes, Failures);
   testsIntWithZero<uint32_t, int32_t>(TotalTests, Passes, Failures);
   testsIntWithZero<uint64, int64>(TotalTests, Passes, Failures);
   testsVecInt<v4ui32, v4si32>(TotalTests, Passes, Failures);
   testsVecInt<v8ui16, v8si16>(TotalTests, Passes, Failures);
   testsVecInt<v16ui8, v16si8>(TotalTests, Passes, Failures);
   testsVecI1<v4i1>(TotalTests, Passes, Failures);
   testsVecI1<v8i1>(TotalTests, Passes, Failures);
   testsVecI1<v16i1>(TotalTests, Passes, Failures);

   std::cout << "TotalTests=" << TotalTests << " Passes=" << Passes
             << " Failures=" << Failures << "\n";
   return Failures;
 }
	//===- subzero/crosstest/test_icmp_main.cpp - Driver for tests. -----------===//
	//
	// The Subzero Code Generator
	//
	// This file is distributed under the University of Illinois Open Source
	// License. See LICENSE.TXT for details.
	//
	//===----------------------------------------------------------------------===//
	//
	// Driver for cross testing the icmp bitcode instruction
	//
	//===----------------------------------------------------------------------===//

	/* crosstest.py --test=test_icmp.cpp --test=test_icmp_i1vec.ll \
	--driver=test_icmp_main.cpp --prefix=Subzero_ --output=test_icmp */

	#include <climits> // CHAR_BIT
	#include <cstring> // memcmp, memset
	#include <stdint.h>
	#include <iostream>

	// Include test_icmp.h twice - once normally, and once within the
	// Subzero_ namespace, corresponding to the llc and Subzero translated
	// object files, respectively.
	#include "test_icmp.h"

	namespace Subzero_ {
	#include "test_icmp.h"
	}

	#include "insertelement.h"
	#include "xdefs.h"

	volatile unsigned Values[] = {
	0x0, 0x1, 0x7ffffffe, 0x7fffffff, 0x80000000, 0x80000001,
	0xfffffffe, 0xffffffff, 0x7e, 0x7f, 0x80, 0x81,
	0xfe, 0xff, 0x100, 0x101, 0x7ffe, 0x7fff,
	0x8000, 0x8001, 0xfffe, 0xffff, 0x10000, 0x10001,
	};
	const static size_t NumValues = sizeof(Values) / sizeof(*Values);

	template <typename TypeUnsigned, typename TypeSigned>
	void testsInt(size_t &TotalTests, size_t &Passes, size_t &Failures) {
	typedef bool (*FuncTypeUnsigned)(TypeUnsigned, TypeUnsigned);
	typedef bool (*FuncTypeSigned)(TypeSigned, TypeSigned);
	static struct {
	const char *Name;
	FuncTypeUnsigned FuncLlc;
	FuncTypeUnsigned FuncSz;
	} Funcs[] = {
	#define X(cmp, op) \
	{ \
	STR(cmp), (FuncTypeUnsigned)icmp##cmp, \
	(FuncTypeUnsigned)Subzero_::icmp##cmp \
	} \
	,
	ICMP_U_TABLE
	#undef X
	#define X(cmp, op) \
	{ \
	STR(cmp), (FuncTypeUnsigned)(FuncTypeSigned)icmp##cmp, \
	(FuncTypeUnsigned)(FuncTypeSigned)Subzero_::icmp##cmp \
	} \
	,
	ICMP_S_TABLE
	#undef X
	};
	const static size_t NumFuncs = sizeof(Funcs) / sizeof(*Funcs);

	if (sizeof(TypeUnsigned) <= sizeof(uint32_t)) {
	// This is the "normal" version of the loop nest, for 32-bit or
	// narrower types.
	for (size_t f = 0; f < NumFuncs; ++f) {
	for (size_t i = 0; i < NumValues; ++i) {
	for (size_t j = 0; j < NumValues; ++j) {
	TypeUnsigned Value1 = Values[i];
	TypeUnsigned Value2 = Values[j];
	++TotalTests;
	bool ResultSz = Funcs[f].FuncSz(Value1, Value2);
	bool ResultLlc = Funcs[f].FuncLlc(Value1, Value2);
	if (ResultSz == ResultLlc) {
	++Passes;
	} else {
	++Failures;
	std::cout << "icmp" << Funcs[f].Name
	<< (CHAR_BIT * sizeof(TypeUnsigned)) << "(" << Value1
	<< ", " << Value2 << "): sz=" << ResultSz
	<< " llc=" << ResultLlc << "\n";
	}
	}
	}
	}
	} else {
	// This is the 64-bit version. Test values are synthesized from
	// the 32-bit values in Values[].
	for (size_t f = 0; f < NumFuncs; ++f) {
	for (size_t iLo = 0; iLo < NumValues; ++iLo) {
	for (size_t iHi = 0; iHi < NumValues; ++iHi) {
	for (size_t jLo = 0; jLo < NumValues; ++jLo) {
	for (size_t jHi = 0; jHi < NumValues; ++jHi) {
	TypeUnsigned Value1 =
	(((TypeUnsigned)Values[iHi]) << 32) + Values[iLo];
	TypeUnsigned Value2 =
	(((TypeUnsigned)Values[jHi]) << 32) + Values[jLo];
	++TotalTests;
	bool ResultSz = Funcs[f].FuncSz(Value1, Value2);
	bool ResultLlc = Funcs[f].FuncLlc(Value1, Value2);
	if (ResultSz == ResultLlc) {
	++Passes;
	} else {
	++Failures;
	std::cout << "icmp" << Funcs[f].Name
	<< (CHAR_BIT * sizeof(TypeUnsigned)) << "(" << Value1
	<< ", " << Value2 << "): sz=" << ResultSz
	<< " llc=" << ResultLlc << "\n";
	}
	}
	}
	}
	}
	}
	}
	}

	template <typename TypeUnsigned, typename TypeSigned>
	void testsIntWithZero(size_t &TotalTests, size_t &Passes, size_t &Failures) {
	typedef bool (*FuncTypeUnsigned)(TypeUnsigned);
	typedef bool (*FuncTypeSigned)(TypeSigned);
	static struct {
	const char *Name;
	FuncTypeUnsigned FuncLlc;
	FuncTypeUnsigned FuncSz;
	} Funcs[] = {
	#define X(cmp, op) \
	{ \
	STR(cmp), (FuncTypeUnsigned)icmp_zero##cmp, \
	(FuncTypeUnsigned)Subzero_::icmp_zero##cmp \
	} \
	,
	ICMP_U_TABLE
	#undef X
	#define X(cmp, op) \
	{ \
	STR(cmp), (FuncTypeUnsigned)(FuncTypeSigned)icmp_zero##cmp, \
	(FuncTypeUnsigned)(FuncTypeSigned)Subzero_::icmp_zero##cmp \
	} \
	,
	ICMP_S_TABLE
	#undef X
	};
	const static size_t NumFuncs = sizeof(Funcs) / sizeof(*Funcs);

	if (sizeof(TypeUnsigned) <= sizeof(uint32_t)) {
	// This is the "normal" version of the loop nest, for 32-bit or
	// narrower types.
	for (size_t f = 0; f < NumFuncs; ++f) {
	for (size_t i = 0; i < NumValues; ++i) {
	TypeUnsigned Value = Values[i];
	++TotalTests;
	bool ResultSz = Funcs[f].FuncSz(Value);
	bool ResultLlc = Funcs[f].FuncLlc(Value);
	if (ResultSz == ResultLlc) {
	++Passes;
	} else {
	++Failures;
	std::cout << "icmp" << Funcs[f].Name
	<< (CHAR_BIT * sizeof(TypeUnsigned)) << "(" << Value
	<< "): sz=" << ResultSz << " llc=" << ResultLlc << "\n";
	}
	}
	}
	} else {
	// This is the 64-bit version. Test values are synthesized from
	// the 32-bit values in Values[].
	for (size_t f = 0; f < NumFuncs; ++f) {
	for (size_t iLo = 0; iLo < NumValues; ++iLo) {
	for (size_t iHi = 0; iHi < NumValues; ++iHi) {
	TypeUnsigned Value =
	(((TypeUnsigned)Values[iHi]) << 32) + Values[iLo];
	++TotalTests;
	bool ResultSz = Funcs[f].FuncSz(Value);
	bool ResultLlc = Funcs[f].FuncLlc(Value);
	if (ResultSz == ResultLlc) {
	++Passes;
	} else {
	++Failures;
	std::cout << "icmp" << Funcs[f].Name
	<< (CHAR_BIT * sizeof(TypeUnsigned)) << "(" << Value
	<< "): sz=" << ResultSz << " llc=" << ResultLlc << "\n";
	}
	}
	}
	}
	}
	}

	const static size_t MaxTestsPerFunc = 100000;

	template <typename TypeUnsignedLabel, typename TypeSignedLabel>
	void testsVecInt(size_t &TotalTests, size_t &Passes, size_t &Failures) {
	typedef typename Vectors<TypeUnsignedLabel>::Ty TypeUnsigned;
	typedef typename Vectors<TypeSignedLabel>::Ty TypeSigned;
	typedef typename Vectors<TypeUnsignedLabel>::ElementTy ElementTypeUnsigned;
	typedef typename Vectors<TypeSignedLabel>::ElementTy ElementTypeSigned;
	typedef TypeUnsigned (*FuncTypeUnsigned)(TypeUnsigned, TypeUnsigned);
	typedef TypeSigned (*FuncTypeSigned)(TypeSigned, TypeSigned);
	static struct {
	const char *Name;
	FuncTypeUnsigned FuncLlc;
	FuncTypeUnsigned FuncSz;
	} Funcs[] = {
	#define X(cmp, op) \
	{ \
	STR(cmp), (FuncTypeUnsigned)icmp##cmp, \
	(FuncTypeUnsigned)Subzero_::icmp##cmp \
	} \
	,
	ICMP_U_TABLE
	#undef X
	#define X(cmp, op) \
	{ \
	STR(cmp), (FuncTypeUnsigned)(FuncTypeSigned)icmp##cmp, \
	(FuncTypeUnsigned)(FuncTypeSigned)Subzero_::icmp##cmp \
	} \
	,
	ICMP_S_TABLE
	#undef X
	};
	const static size_t NumFuncs = sizeof(Funcs) / sizeof(*Funcs);
	const static size_t NumElementsInType = Vectors<TypeUnsigned>::NumElements;
	for (size_t f = 0; f < NumFuncs; ++f) {
	PRNG Index;
	for (size_t i = 0; i < MaxTestsPerFunc; ++i) {
	// Initialize the test vectors.
	TypeUnsigned Value1, Value2;
	for (size_t j = 0; j < NumElementsInType; ++j) {
	setElement(Value1, j, Values[Index() % NumValues]);
	setElement(Value2, j, Values[Index() % NumValues]);
	}
	// Perform the test.
	TypeUnsigned ResultSz = Funcs[f].FuncSz(Value1, Value2);
	TypeUnsigned ResultLlc = Funcs[f].FuncLlc(Value1, Value2);
	++TotalTests;
	if (!memcmp(&ResultSz, &ResultLlc, sizeof(ResultSz))) {
	++Passes;
	} else {
	++Failures;
	std::cout << "test" << Funcs[f].Name
	<< Vectors<TypeUnsignedLabel>::TypeName << "("
	<< vectAsString<TypeUnsignedLabel>(Value1) << ","
	<< vectAsString<TypeUnsignedLabel>(Value2)
	<< "): sz=" << vectAsString<TypeUnsignedLabel>(ResultSz)
	<< " llc=" << vectAsString<TypeUnsignedLabel>(ResultLlc)
	<< "\n";
	}
	}
	}
	}

	// Return true on wraparound
	template <typename T>
	bool __attribute__((noinline))
	incrementI1Vector(typename Vectors<T>::Ty &Vect) {
	size_t Pos = 0;
	const static size_t NumElements = Vectors<T>::NumElements;
	for (Pos = 0; Pos < NumElements; ++Pos) {
	if (Vect[Pos] == 0) {
	Vect[Pos] = 1;
	break;
	}
	Vect[Pos] = 0;
	}
	return (Pos == NumElements);
	}

	template <typename T>
	void testsVecI1(size_t &TotalTests, size_t &Passes, size_t &Failures) {
	typedef typename Vectors<T>::Ty Ty;
	typedef Ty (*FuncType)(Ty, Ty);
	static struct {
	const char *Name;
	FuncType FuncLlc;
	FuncType FuncSz;
	} Funcs[] = {
	#define X(cmp, op) \
	{ STR(cmp), (FuncType)icmpi1##cmp, (FuncType)Subzero_::icmpi1##cmp } \
	,
	ICMP_U_TABLE ICMP_S_TABLE};
	const static size_t NumFuncs = sizeof(Funcs) / sizeof(*Funcs);
	const static size_t NumElements = Vectors<T>::NumElements;
	const static size_t MAX_NUMBER_OF_ELEMENTS_FOR_EXHAUSTIVE_TESTING = 8;

	// Check if the type is small enough to try all possible input pairs.
	if (NumElements <= MAX_NUMBER_OF_ELEMENTS_FOR_EXHAUSTIVE_TESTING) {
	for (size_t f = 0; f < NumFuncs; ++f) {
	Ty Value1, Value2;
	memset(&Value1, 0, sizeof(Value1));
	for (bool IsValue1Done = false; !IsValue1Done;
	IsValue1Done = incrementI1Vector<T>(Value1)) {
	memset(&Value2, 0, sizeof(Value2));
	for (bool IsValue2Done = false; !IsValue2Done;
	IsValue2Done = incrementI1Vector<T>(Value2)) {
	Ty ResultSz = Funcs[f].FuncSz(Value1, Value2);
	Ty ResultLlc = Funcs[f].FuncLlc(Value1, Value2);
	++TotalTests;
	if (!memcmp(&ResultSz, &ResultLlc, sizeof(ResultSz))) {
	++Passes;
	} else {
	++Failures;
	std::cout << "test" << Funcs[f].Name << Vectors<T>::TypeName << "("
	<< vectAsString<T>(Value1) << ","
	<< vectAsString<T>(Value2)
	<< "): sz=" << vectAsString<T>(ResultSz)
	<< " llc=" << vectAsString<T>(ResultLlc) << "\n";
	}
	}
	}
	}
	} else {
	for (size_t f = 0; f < NumFuncs; ++f) {
	PRNG Index;
	for (size_t i = 0; i < MaxTestsPerFunc; ++i) {
	Ty Value1, Value2;
	// Initialize the test vectors.
	for (size_t j = 0; j < NumElements; ++j) {
	setElement(Value1, j, Index() % 2);
	setElement(Value2, j, Index() % 2);
	}
	// Perform the test.
	Ty ResultSz = Funcs[f].FuncSz(Value1, Value2);
	Ty ResultLlc = Funcs[f].FuncLlc(Value1, Value2);
	++TotalTests;
	if (!memcmp(&ResultSz, &ResultLlc, sizeof(ResultSz))) {
	++Passes;
	} else {
	++Failures;
	std::cout << "test" << Funcs[f].Name << Vectors<T>::TypeName << "("
	<< vectAsString<T>(Value1) << "," << vectAsString<T>(Value2)
	<< "): sz=" << vectAsString<T>(ResultSz)
	<< " llc=" << vectAsString<T>(ResultLlc) << "\n";
	}
	}
	}
	}
	}

	int main(int argc, char *argv[]) {
	size_t TotalTests = 0;
	size_t Passes = 0;
	size_t Failures = 0;

	testsInt<uint8_t, myint8_t>(TotalTests, Passes, Failures);
	testsInt<uint16_t, int16_t>(TotalTests, Passes, Failures);
	testsInt<uint32_t, int32_t>(TotalTests, Passes, Failures);
	testsInt<uint64, int64>(TotalTests, Passes, Failures);
	testsIntWithZero<uint8_t, myint8_t>(TotalTests, Passes, Failures);
	testsIntWithZero<uint16_t, int16_t>(TotalTests, Passes, Failures);
	testsIntWithZero<uint32_t, int32_t>(TotalTests, Passes, Failures);
	testsIntWithZero<uint64, int64>(TotalTests, Passes, Failures);
	testsVecInt<v4ui32, v4si32>(TotalTests, Passes, Failures);
	testsVecInt<v8ui16, v8si16>(TotalTests, Passes, Failures);
	testsVecInt<v16ui8, v16si8>(TotalTests, Passes, Failures);
	testsVecI1<v4i1>(TotalTests, Passes, Failures);
	testsVecI1<v8i1>(TotalTests, Passes, Failures);
	testsVecI1<v16i1>(TotalTests, Passes, Failures);

	std::cout << "TotalTests=" << TotalTests << " Passes=" << Passes
	<< " Failures=" << Failures << "\n";
	return Failures;
	}