src/v8/test/cctest/test-utils-arm64.cc - cobalt - Git at Google

 // Copyright 2013 the V8 project authors. All rights reserved.
 // Redistribution and use in source and binary forms, with or without
 // modification, are permitted provided that the following conditions are
 // met:
 //
 //     * Redistributions of source code must retain the above copyright
 //       notice, this list of conditions and the following disclaimer.
 //     * Redistributions in binary form must reproduce the above
 //       copyright notice, this list of conditions and the following
 //       disclaimer in the documentation and/or other materials provided
 //       with the distribution.
 //     * Neither the name of Google Inc. nor the names of its
 //       contributors may be used to endorse or promote products derived
 //       from this software without specific prior written permission.
 //
 // THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
 // "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
 // LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
 // A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
 // OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
 // SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
 // LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
 // DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
 // THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
 // (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
 // OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.

 #include "src/v8.h"

 #include "src/arm64/assembler-arm64-inl.h"
 #include "src/arm64/utils-arm64.h"
 #include "src/base/template-utils.h"
 #include "src/macro-assembler-inl.h"
 #include "test/cctest/cctest.h"
 #include "test/cctest/test-utils-arm64.h"

 namespace v8 {
 namespace internal {


 #define __ masm->


 bool Equal32(uint32_t expected, const RegisterDump*, uint32_t result) {
   if (result != expected) {
     printf("Expected 0x%08" PRIx32 "\t Found 0x%08" PRIx32 "\n",
            expected, result);
   }

   return expected == result;
 }


 bool Equal64(uint64_t expected, const RegisterDump*, uint64_t result) {
   if (result != expected) {
     printf("Expected 0x%016" PRIx64 "\t Found 0x%016" PRIx64 "\n",
            expected, result);
   }

   return expected == result;
 }

 bool Equal128(vec128_t expected, const RegisterDump*, vec128_t result) {
   if ((result.h != expected.h) || (result.l != expected.l)) {
     printf("Expected 0x%016" PRIx64 "%016" PRIx64
            "\t "
            "Found 0x%016" PRIx64 "%016" PRIx64 "\n",
            expected.h, expected.l, result.h, result.l);
   }

   return ((expected.h == result.h) && (expected.l == result.l));
 }

 bool EqualFP32(float expected, const RegisterDump*, float result) {
   if (bit_cast<uint32_t>(expected) == bit_cast<uint32_t>(result)) {
     return true;
   } else {
     if (std::isnan(expected) || (expected == 0.0)) {
       printf("Expected 0x%08" PRIx32 "\t Found 0x%08" PRIx32 "\n",
              bit_cast<uint32_t>(expected), bit_cast<uint32_t>(result));
     } else {
       printf("Expected %.9f (0x%08" PRIx32
              ")\t "
              "Found %.9f (0x%08" PRIx32 ")\n",
              expected, bit_cast<uint32_t>(expected), result,
              bit_cast<uint32_t>(result));
     }
     return false;
   }
 }


 bool EqualFP64(double expected, const RegisterDump*, double result) {
   if (bit_cast<uint64_t>(expected) == bit_cast<uint64_t>(result)) {
     return true;
   }

   if (std::isnan(expected) || (expected == 0.0)) {
     printf("Expected 0x%016" PRIx64 "\t Found 0x%016" PRIx64 "\n",
            bit_cast<uint64_t>(expected), bit_cast<uint64_t>(result));
   } else {
     printf("Expected %.17f (0x%016" PRIx64
            ")\t "
            "Found %.17f (0x%016" PRIx64 ")\n",
            expected, bit_cast<uint64_t>(expected), result,
            bit_cast<uint64_t>(result));
   }
   return false;
 }


 bool Equal32(uint32_t expected, const RegisterDump* core, const Register& reg) {
   CHECK(reg.Is32Bits());
   // Retrieve the corresponding X register so we can check that the upper part
   // was properly cleared.
   int64_t result_x = core->xreg(reg.code());
   if ((result_x & 0xFFFFFFFF00000000L) != 0) {
     printf("Expected 0x%08" PRIx32 "\t Found 0x%016" PRIx64 "\n",
            expected, result_x);
     return false;
   }
   uint32_t result_w = core->wreg(reg.code());
   return Equal32(expected, core, result_w);
 }


 bool Equal64(uint64_t expected,
              const RegisterDump* core,
              const Register& reg) {
   CHECK(reg.Is64Bits());
   uint64_t result = core->xreg(reg.code());
   return Equal64(expected, core, result);
 }

 bool Equal128(uint64_t expected_h, uint64_t expected_l,
               const RegisterDump* core, const VRegister& vreg) {
   CHECK(vreg.Is128Bits());
   vec128_t expected = {expected_l, expected_h};
   vec128_t result = core->qreg(vreg.code());
   return Equal128(expected, core, result);
 }

 bool EqualFP32(float expected, const RegisterDump* core,
                const VRegister& fpreg) {
   CHECK(fpreg.Is32Bits());
   // Retrieve the corresponding D register so we can check that the upper part
   // was properly cleared.
   uint64_t result_64 = core->dreg_bits(fpreg.code());
   if ((result_64 & 0xFFFFFFFF00000000L) != 0) {
     printf("Expected 0x%08" PRIx32 " (%f)\t Found 0x%016" PRIx64 "\n",
            bit_cast<uint32_t>(expected), expected, result_64);
     return false;
   }

   return EqualFP32(expected, core, core->sreg(fpreg.code()));
 }

 bool EqualFP64(double expected, const RegisterDump* core,
                const VRegister& fpreg) {
   CHECK(fpreg.Is64Bits());
   return EqualFP64(expected, core, core->dreg(fpreg.code()));
 }


 bool Equal64(const Register& reg0,
              const RegisterDump* core,
              const Register& reg1) {
   CHECK(reg0.Is64Bits() && reg1.Is64Bits());
   int64_t expected = core->xreg(reg0.code());
   int64_t result = core->xreg(reg1.code());
   return Equal64(expected, core, result);
 }


 static char FlagN(uint32_t flags) {
   return (flags & NFlag) ? 'N' : 'n';
 }


 static char FlagZ(uint32_t flags) {
   return (flags & ZFlag) ? 'Z' : 'z';
 }


 static char FlagC(uint32_t flags) {
   return (flags & CFlag) ? 'C' : 'c';
 }


 static char FlagV(uint32_t flags) {
   return (flags & VFlag) ? 'V' : 'v';
 }


 bool EqualNzcv(uint32_t expected, uint32_t result) {
   CHECK_EQ(expected & ~NZCVFlag, 0);
   CHECK_EQ(result & ~NZCVFlag, 0);
   if (result != expected) {
     printf("Expected: %c%c%c%c\t Found: %c%c%c%c\n",
         FlagN(expected), FlagZ(expected), FlagC(expected), FlagV(expected),
         FlagN(result), FlagZ(result), FlagC(result), FlagV(result));
     return false;
   }

   return true;
 }


 bool EqualRegisters(const RegisterDump* a, const RegisterDump* b) {
   for (unsigned i = 0; i < kNumberOfRegisters; i++) {
     if (a->xreg(i) != b->xreg(i)) {
       printf("x%d\t Expected 0x%016" PRIx64 "\t Found 0x%016" PRIx64 "\n",
              i, a->xreg(i), b->xreg(i));
       return false;
     }
   }

   for (unsigned i = 0; i < kNumberOfVRegisters; i++) {
     uint64_t a_bits = a->dreg_bits(i);
     uint64_t b_bits = b->dreg_bits(i);
     if (a_bits != b_bits) {
       printf("d%d\t Expected 0x%016" PRIx64 "\t Found 0x%016" PRIx64 "\n",
              i, a_bits, b_bits);
       return false;
     }
   }

   return true;
 }

 RegList PopulateRegisterArray(Register* w, Register* x, Register* r,
                               int reg_size, int reg_count, RegList allowed) {
   RegList list = 0;
   int i = 0;
   for (unsigned n = 0; (n < kNumberOfRegisters) && (i < reg_count); n++) {
     if (((1UL << n) & allowed) != 0) {
       // Only assign allowed registers.
       if (r) {
         r[i] = Register::Create(n, reg_size);
       }
       if (x) {
         x[i] = Register::Create(n, kXRegSizeInBits);
       }
       if (w) {
         w[i] = Register::Create(n, kWRegSizeInBits);
       }
       list |= (1UL << n);
       i++;
     }
   }
   // Check that we got enough registers.
   CHECK(CountSetBits(list, kNumberOfRegisters) == reg_count);

   return list;
 }

 RegList PopulateVRegisterArray(VRegister* s, VRegister* d, VRegister* v,
                                int reg_size, int reg_count, RegList allowed) {
   RegList list = 0;
   int i = 0;
   for (unsigned n = 0; (n < kNumberOfVRegisters) && (i < reg_count); n++) {
     if (((1UL << n) & allowed) != 0) {
       // Only assigned allowed registers.
       if (v) {
         v[i] = VRegister::Create(n, reg_size);
       }
       if (d) {
         d[i] = VRegister::Create(n, kDRegSizeInBits);
       }
       if (s) {
         s[i] = VRegister::Create(n, kSRegSizeInBits);
       }
       list |= (1UL << n);
       i++;
     }
   }
   // Check that we got enough registers.
   CHECK(CountSetBits(list, kNumberOfVRegisters) == reg_count);

   return list;
 }


 void Clobber(MacroAssembler* masm, RegList reg_list, uint64_t const value) {
   Register first = NoReg;
   for (unsigned i = 0; i < kNumberOfRegisters; i++) {
     if (reg_list & (1UL << i)) {
       Register xn = Register::Create(i, kXRegSizeInBits);
       // We should never write into csp here.
       CHECK(!xn.Is(csp));
       if (!xn.IsZero()) {
         if (!first.IsValid()) {
           // This is the first register we've hit, so construct the literal.
           __ Mov(xn, value);
           first = xn;
         } else {
           // We've already loaded the literal, so re-use the value already
           // loaded into the first register we hit.
           __ Mov(xn, first);
         }
       }
     }
   }
 }


 void ClobberFP(MacroAssembler* masm, RegList reg_list, double const value) {
   VRegister first = NoVReg;
   for (unsigned i = 0; i < kNumberOfVRegisters; i++) {
     if (reg_list & (1UL << i)) {
       VRegister dn = VRegister::Create(i, kDRegSizeInBits);
       if (!first.IsValid()) {
         // This is the first register we've hit, so construct the literal.
         __ Fmov(dn, value);
         first = dn;
       } else {
         // We've already loaded the literal, so re-use the value already loaded
         // into the first register we hit.
         __ Fmov(dn, first);
       }
     }
   }
 }


 void Clobber(MacroAssembler* masm, CPURegList reg_list) {
   if (reg_list.type() == CPURegister::kRegister) {
     // This will always clobber X registers.
     Clobber(masm, reg_list.list());
   } else if (reg_list.type() == CPURegister::kVRegister) {
     // This will always clobber D registers.
     ClobberFP(masm, reg_list.list());
   } else {
     UNREACHABLE();
   }
 }


 void RegisterDump::Dump(MacroAssembler* masm) {
   CHECK(__ StackPointer().Is(csp));

   // Ensure that we don't unintentionally clobber any registers.
   RegList old_tmp_list = masm->TmpList()->list();
   RegList old_fptmp_list = masm->FPTmpList()->list();
   masm->TmpList()->set_list(0);
   masm->FPTmpList()->set_list(0);

   // Preserve some temporary registers.
   Register dump_base = x0;
   Register dump = x1;
   Register tmp = x2;
   Register dump_base_w = dump_base.W();
   Register dump_w = dump.W();
   Register tmp_w = tmp.W();

   // Offsets into the dump_ structure.
   const int x_offset = offsetof(dump_t, x_);
   const int w_offset = offsetof(dump_t, w_);
   const int d_offset = offsetof(dump_t, d_);
   const int s_offset = offsetof(dump_t, s_);
   const int q_offset = offsetof(dump_t, q_);
   const int sp_offset = offsetof(dump_t, sp_);
   const int wsp_offset = offsetof(dump_t, wsp_);
   const int flags_offset = offsetof(dump_t, flags_);

   __ Push(xzr, dump_base, dump, tmp);

   // Load the address where we will dump the state.
   __ Mov(dump_base, reinterpret_cast<uint64_t>(&dump_));

   // Dump the stack pointer (csp and wcsp).
   // The stack pointer cannot be stored directly; it needs to be moved into
   // another register first. Also, we pushed four X registers, so we need to
   // compensate here.
   __ Add(tmp, csp, 4 * kXRegSize);
   __ Str(tmp, MemOperand(dump_base, sp_offset));
   __ Add(tmp_w, wcsp, 4 * kXRegSize);
   __ Str(tmp_w, MemOperand(dump_base, wsp_offset));

   // Dump X registers.
   __ Add(dump, dump_base, x_offset);
   for (unsigned i = 0; i < kNumberOfRegisters; i += 2) {
     __ Stp(Register::XRegFromCode(i), Register::XRegFromCode(i + 1),
            MemOperand(dump, i * kXRegSize));
   }

   // Dump W registers.
   __ Add(dump, dump_base, w_offset);
   for (unsigned i = 0; i < kNumberOfRegisters; i += 2) {
     __ Stp(Register::WRegFromCode(i), Register::WRegFromCode(i + 1),
            MemOperand(dump, i * kWRegSize));
   }

   // Dump D registers.
   __ Add(dump, dump_base, d_offset);
   for (unsigned i = 0; i < kNumberOfVRegisters; i += 2) {
     __ Stp(VRegister::DRegFromCode(i), VRegister::DRegFromCode(i + 1),
            MemOperand(dump, i * kDRegSize));
   }

   // Dump S registers.
   __ Add(dump, dump_base, s_offset);
   for (unsigned i = 0; i < kNumberOfVRegisters; i += 2) {
     __ Stp(VRegister::SRegFromCode(i), VRegister::SRegFromCode(i + 1),
            MemOperand(dump, i * kSRegSize));
   }

   // Dump Q registers.
   __ Add(dump, dump_base, q_offset);
   for (unsigned i = 0; i < kNumberOfVRegisters; i += 2) {
     __ Stp(VRegister::QRegFromCode(i), VRegister::QRegFromCode(i + 1),
            MemOperand(dump, i * kQRegSize));
   }

   // Dump the flags.
   __ Mrs(tmp, NZCV);
   __ Str(tmp, MemOperand(dump_base, flags_offset));

   // To dump the values that were in tmp amd dump, we need a new scratch
   // register.  We can use any of the already dumped registers since we can
   // easily restore them.
   Register dump2_base = x10;
   Register dump2 = x11;
   CHECK(!AreAliased(dump_base, dump, tmp, dump2_base, dump2));

   // Don't lose the dump_ address.
   __ Mov(dump2_base, dump_base);

   __ Pop(tmp, dump, dump_base, xzr);

   __ Add(dump2, dump2_base, w_offset);
   __ Str(dump_base_w, MemOperand(dump2, dump_base.code() * kWRegSize));
   __ Str(dump_w, MemOperand(dump2, dump.code() * kWRegSize));
   __ Str(tmp_w, MemOperand(dump2, tmp.code() * kWRegSize));

   __ Add(dump2, dump2_base, x_offset);
   __ Str(dump_base, MemOperand(dump2, dump_base.code() * kXRegSize));
   __ Str(dump, MemOperand(dump2, dump.code() * kXRegSize));
   __ Str(tmp, MemOperand(dump2, tmp.code() * kXRegSize));

   // Finally, restore dump2_base and dump2.
   __ Ldr(dump2_base, MemOperand(dump2, dump2_base.code() * kXRegSize));
   __ Ldr(dump2, MemOperand(dump2, dump2.code() * kXRegSize));

   // Restore the MacroAssembler's scratch registers.
   masm->TmpList()->set_list(old_tmp_list);
   masm->FPTmpList()->set_list(old_fptmp_list);

   completed_ = true;
 }

 }  // namespace internal
 }  // namespace v8

 #undef __
	// Copyright 2013 the V8 project authors. All rights reserved.
	// Redistribution and use in source and binary forms, with or without
	// modification, are permitted provided that the following conditions are
	// met:
	//
	// * Redistributions of source code must retain the above copyright
	// notice, this list of conditions and the following disclaimer.
	// * Redistributions in binary form must reproduce the above
	// copyright notice, this list of conditions and the following
	// disclaimer in the documentation and/or other materials provided
	// with the distribution.
	// * Neither the name of Google Inc. nor the names of its
	// contributors may be used to endorse or promote products derived
	// from this software without specific prior written permission.
	//
	// THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
	// "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
	// LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
	// A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
	// OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
	// SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
	// LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
	// DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
	// THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
	// (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
	// OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.

	#include "src/v8.h"

	#include "src/arm64/assembler-arm64-inl.h"
	#include "src/arm64/utils-arm64.h"
	#include "src/base/template-utils.h"
	#include "src/macro-assembler-inl.h"
	#include "test/cctest/cctest.h"
	#include "test/cctest/test-utils-arm64.h"

	namespace v8 {
	namespace internal {


	#define __ masm->


	bool Equal32(uint32_t expected, const RegisterDump*, uint32_t result) {
	if (result != expected) {
	printf("Expected 0x%08" PRIx32 "\t Found 0x%08" PRIx32 "\n",
	expected, result);
	}

	return expected == result;
	}


	bool Equal64(uint64_t expected, const RegisterDump*, uint64_t result) {
	if (result != expected) {
	printf("Expected 0x%016" PRIx64 "\t Found 0x%016" PRIx64 "\n",
	expected, result);
	}

	return expected == result;
	}

	bool Equal128(vec128_t expected, const RegisterDump*, vec128_t result) {
	if ((result.h != expected.h) \|\| (result.l != expected.l)) {
	printf("Expected 0x%016" PRIx64 "%016" PRIx64
	"\t "
	"Found 0x%016" PRIx64 "%016" PRIx64 "\n",
	expected.h, expected.l, result.h, result.l);
	}

	return ((expected.h == result.h) && (expected.l == result.l));
	}

	bool EqualFP32(float expected, const RegisterDump*, float result) {
	if (bit_cast<uint32_t>(expected) == bit_cast<uint32_t>(result)) {
	return true;
	} else {
	if (std::isnan(expected) \|\| (expected == 0.0)) {
	printf("Expected 0x%08" PRIx32 "\t Found 0x%08" PRIx32 "\n",
	bit_cast<uint32_t>(expected), bit_cast<uint32_t>(result));
	} else {
	printf("Expected %.9f (0x%08" PRIx32
	")\t "
	"Found %.9f (0x%08" PRIx32 ")\n",
	expected, bit_cast<uint32_t>(expected), result,
	bit_cast<uint32_t>(result));
	}
	return false;
	}
	}


	bool EqualFP64(double expected, const RegisterDump*, double result) {
	if (bit_cast<uint64_t>(expected) == bit_cast<uint64_t>(result)) {
	return true;
	}

	if (std::isnan(expected) \|\| (expected == 0.0)) {
	printf("Expected 0x%016" PRIx64 "\t Found 0x%016" PRIx64 "\n",
	bit_cast<uint64_t>(expected), bit_cast<uint64_t>(result));
	} else {
	printf("Expected %.17f (0x%016" PRIx64
	")\t "
	"Found %.17f (0x%016" PRIx64 ")\n",
	expected, bit_cast<uint64_t>(expected), result,
	bit_cast<uint64_t>(result));
	}
	return false;
	}


	bool Equal32(uint32_t expected, const RegisterDump* core, const Register& reg) {
	CHECK(reg.Is32Bits());
	// Retrieve the corresponding X register so we can check that the upper part
	// was properly cleared.
	int64_t result_x = core->xreg(reg.code());
	if ((result_x & 0xFFFFFFFF00000000L) != 0) {
	printf("Expected 0x%08" PRIx32 "\t Found 0x%016" PRIx64 "\n",
	expected, result_x);
	return false;
	}
	uint32_t result_w = core->wreg(reg.code());
	return Equal32(expected, core, result_w);
	}


	bool Equal64(uint64_t expected,
	const RegisterDump* core,
	const Register& reg) {
	CHECK(reg.Is64Bits());
	uint64_t result = core->xreg(reg.code());
	return Equal64(expected, core, result);
	}

	bool Equal128(uint64_t expected_h, uint64_t expected_l,
	const RegisterDump* core, const VRegister& vreg) {
	CHECK(vreg.Is128Bits());
	vec128_t expected = {expected_l, expected_h};
	vec128_t result = core->qreg(vreg.code());
	return Equal128(expected, core, result);
	}

	bool EqualFP32(float expected, const RegisterDump* core,
	const VRegister& fpreg) {
	CHECK(fpreg.Is32Bits());
	// Retrieve the corresponding D register so we can check that the upper part
	// was properly cleared.
	uint64_t result_64 = core->dreg_bits(fpreg.code());
	if ((result_64 & 0xFFFFFFFF00000000L) != 0) {
	printf("Expected 0x%08" PRIx32 " (%f)\t Found 0x%016" PRIx64 "\n",
	bit_cast<uint32_t>(expected), expected, result_64);
	return false;
	}

	return EqualFP32(expected, core, core->sreg(fpreg.code()));
	}

	bool EqualFP64(double expected, const RegisterDump* core,
	const VRegister& fpreg) {
	CHECK(fpreg.Is64Bits());
	return EqualFP64(expected, core, core->dreg(fpreg.code()));
	}


	bool Equal64(const Register& reg0,
	const RegisterDump* core,
	const Register& reg1) {
	CHECK(reg0.Is64Bits() && reg1.Is64Bits());
	int64_t expected = core->xreg(reg0.code());
	int64_t result = core->xreg(reg1.code());
	return Equal64(expected, core, result);
	}


	static char FlagN(uint32_t flags) {
	return (flags & NFlag) ? 'N' : 'n';
	}


	static char FlagZ(uint32_t flags) {
	return (flags & ZFlag) ? 'Z' : 'z';
	}


	static char FlagC(uint32_t flags) {
	return (flags & CFlag) ? 'C' : 'c';
	}


	static char FlagV(uint32_t flags) {
	return (flags & VFlag) ? 'V' : 'v';
	}


	bool EqualNzcv(uint32_t expected, uint32_t result) {
	CHECK_EQ(expected & ~NZCVFlag, 0);
	CHECK_EQ(result & ~NZCVFlag, 0);
	if (result != expected) {
	printf("Expected: %c%c%c%c\t Found: %c%c%c%c\n",
	FlagN(expected), FlagZ(expected), FlagC(expected), FlagV(expected),
	FlagN(result), FlagZ(result), FlagC(result), FlagV(result));
	return false;
	}

	return true;
	}


	bool EqualRegisters(const RegisterDump* a, const RegisterDump* b) {
	for (unsigned i = 0; i < kNumberOfRegisters; i++) {
	if (a->xreg(i) != b->xreg(i)) {
	printf("x%d\t Expected 0x%016" PRIx64 "\t Found 0x%016" PRIx64 "\n",
	i, a->xreg(i), b->xreg(i));
	return false;
	}
	}

	for (unsigned i = 0; i < kNumberOfVRegisters; i++) {
	uint64_t a_bits = a->dreg_bits(i);
	uint64_t b_bits = b->dreg_bits(i);
	if (a_bits != b_bits) {
	printf("d%d\t Expected 0x%016" PRIx64 "\t Found 0x%016" PRIx64 "\n",
	i, a_bits, b_bits);
	return false;
	}
	}

	return true;
	}

	RegList PopulateRegisterArray(Register* w, Register* x, Register* r,
	int reg_size, int reg_count, RegList allowed) {
	RegList list = 0;
	int i = 0;
	for (unsigned n = 0; (n < kNumberOfRegisters) && (i < reg_count); n++) {
	if (((1UL << n) & allowed) != 0) {
	// Only assign allowed registers.
	if (r) {
	r[i] = Register::Create(n, reg_size);
	}
	if (x) {
	x[i] = Register::Create(n, kXRegSizeInBits);
	}
	if (w) {
	w[i] = Register::Create(n, kWRegSizeInBits);
	}
	list \|= (1UL << n);
	i++;
	}
	}
	// Check that we got enough registers.
	CHECK(CountSetBits(list, kNumberOfRegisters) == reg_count);

	return list;
	}

	RegList PopulateVRegisterArray(VRegister* s, VRegister* d, VRegister* v,
	int reg_size, int reg_count, RegList allowed) {
	RegList list = 0;
	int i = 0;
	for (unsigned n = 0; (n < kNumberOfVRegisters) && (i < reg_count); n++) {
	if (((1UL << n) & allowed) != 0) {
	// Only assigned allowed registers.
	if (v) {
	v[i] = VRegister::Create(n, reg_size);
	}
	if (d) {
	d[i] = VRegister::Create(n, kDRegSizeInBits);
	}
	if (s) {
	s[i] = VRegister::Create(n, kSRegSizeInBits);
	}
	list \|= (1UL << n);
	i++;
	}
	}
	// Check that we got enough registers.
	CHECK(CountSetBits(list, kNumberOfVRegisters) == reg_count);

	return list;
	}


	void Clobber(MacroAssembler* masm, RegList reg_list, uint64_t const value) {
	Register first = NoReg;
	for (unsigned i = 0; i < kNumberOfRegisters; i++) {
	if (reg_list & (1UL << i)) {
	Register xn = Register::Create(i, kXRegSizeInBits);
	// We should never write into csp here.
	CHECK(!xn.Is(csp));
	if (!xn.IsZero()) {
	if (!first.IsValid()) {
	// This is the first register we've hit, so construct the literal.
	__ Mov(xn, value);
	first = xn;
	} else {
	// We've already loaded the literal, so re-use the value already
	// loaded into the first register we hit.
	__ Mov(xn, first);
	}
	}
	}
	}
	}


	void ClobberFP(MacroAssembler* masm, RegList reg_list, double const value) {
	VRegister first = NoVReg;
	for (unsigned i = 0; i < kNumberOfVRegisters; i++) {
	if (reg_list & (1UL << i)) {
	VRegister dn = VRegister::Create(i, kDRegSizeInBits);
	if (!first.IsValid()) {
	// This is the first register we've hit, so construct the literal.
	__ Fmov(dn, value);
	first = dn;
	} else {
	// We've already loaded the literal, so re-use the value already loaded
	// into the first register we hit.
	__ Fmov(dn, first);
	}
	}
	}
	}


	void Clobber(MacroAssembler* masm, CPURegList reg_list) {
	if (reg_list.type() == CPURegister::kRegister) {
	// This will always clobber X registers.
	Clobber(masm, reg_list.list());
	} else if (reg_list.type() == CPURegister::kVRegister) {
	// This will always clobber D registers.
	ClobberFP(masm, reg_list.list());
	} else {
	UNREACHABLE();
	}
	}


	void RegisterDump::Dump(MacroAssembler* masm) {
	CHECK(__ StackPointer().Is(csp));

	// Ensure that we don't unintentionally clobber any registers.
	RegList old_tmp_list = masm->TmpList()->list();
	RegList old_fptmp_list = masm->FPTmpList()->list();
	masm->TmpList()->set_list(0);
	masm->FPTmpList()->set_list(0);

	// Preserve some temporary registers.
	Register dump_base = x0;
	Register dump = x1;
	Register tmp = x2;
	Register dump_base_w = dump_base.W();
	Register dump_w = dump.W();
	Register tmp_w = tmp.W();

	// Offsets into the dump_ structure.
	const int x_offset = offsetof(dump_t, x_);
	const int w_offset = offsetof(dump_t, w_);
	const int d_offset = offsetof(dump_t, d_);
	const int s_offset = offsetof(dump_t, s_);
	const int q_offset = offsetof(dump_t, q_);
	const int sp_offset = offsetof(dump_t, sp_);
	const int wsp_offset = offsetof(dump_t, wsp_);
	const int flags_offset = offsetof(dump_t, flags_);

	__ Push(xzr, dump_base, dump, tmp);

	// Load the address where we will dump the state.
	__ Mov(dump_base, reinterpret_cast<uint64_t>(&dump_));

	// Dump the stack pointer (csp and wcsp).
	// The stack pointer cannot be stored directly; it needs to be moved into
	// another register first. Also, we pushed four X registers, so we need to
	// compensate here.
	__ Add(tmp, csp, 4 * kXRegSize);
	__ Str(tmp, MemOperand(dump_base, sp_offset));
	__ Add(tmp_w, wcsp, 4 * kXRegSize);
	__ Str(tmp_w, MemOperand(dump_base, wsp_offset));

	// Dump X registers.
	__ Add(dump, dump_base, x_offset);
	for (unsigned i = 0; i < kNumberOfRegisters; i += 2) {
	__ Stp(Register::XRegFromCode(i), Register::XRegFromCode(i + 1),
	MemOperand(dump, i * kXRegSize));
	}

	// Dump W registers.
	__ Add(dump, dump_base, w_offset);
	for (unsigned i = 0; i < kNumberOfRegisters; i += 2) {
	__ Stp(Register::WRegFromCode(i), Register::WRegFromCode(i + 1),
	MemOperand(dump, i * kWRegSize));
	}

	// Dump D registers.
	__ Add(dump, dump_base, d_offset);
	for (unsigned i = 0; i < kNumberOfVRegisters; i += 2) {
	__ Stp(VRegister::DRegFromCode(i), VRegister::DRegFromCode(i + 1),
	MemOperand(dump, i * kDRegSize));
	}

	// Dump S registers.
	__ Add(dump, dump_base, s_offset);
	for (unsigned i = 0; i < kNumberOfVRegisters; i += 2) {
	__ Stp(VRegister::SRegFromCode(i), VRegister::SRegFromCode(i + 1),
	MemOperand(dump, i * kSRegSize));
	}

	// Dump Q registers.
	__ Add(dump, dump_base, q_offset);
	for (unsigned i = 0; i < kNumberOfVRegisters; i += 2) {
	__ Stp(VRegister::QRegFromCode(i), VRegister::QRegFromCode(i + 1),
	MemOperand(dump, i * kQRegSize));
	}

	// Dump the flags.
	__ Mrs(tmp, NZCV);
	__ Str(tmp, MemOperand(dump_base, flags_offset));

	// To dump the values that were in tmp amd dump, we need a new scratch
	// register. We can use any of the already dumped registers since we can
	// easily restore them.
	Register dump2_base = x10;
	Register dump2 = x11;
	CHECK(!AreAliased(dump_base, dump, tmp, dump2_base, dump2));

	// Don't lose the dump_ address.
	__ Mov(dump2_base, dump_base);

	__ Pop(tmp, dump, dump_base, xzr);

	__ Add(dump2, dump2_base, w_offset);
	__ Str(dump_base_w, MemOperand(dump2, dump_base.code() * kWRegSize));
	__ Str(dump_w, MemOperand(dump2, dump.code() * kWRegSize));
	__ Str(tmp_w, MemOperand(dump2, tmp.code() * kWRegSize));

	__ Add(dump2, dump2_base, x_offset);
	__ Str(dump_base, MemOperand(dump2, dump_base.code() * kXRegSize));
	__ Str(dump, MemOperand(dump2, dump.code() * kXRegSize));
	__ Str(tmp, MemOperand(dump2, tmp.code() * kXRegSize));

	// Finally, restore dump2_base and dump2.
	__ Ldr(dump2_base, MemOperand(dump2, dump2_base.code() * kXRegSize));
	__ Ldr(dump2, MemOperand(dump2, dump2.code() * kXRegSize));

	// Restore the MacroAssembler's scratch registers.
	masm->TmpList()->set_list(old_tmp_list);
	masm->FPTmpList()->set_list(old_fptmp_list);

	completed_ = true;
	}

	} // namespace internal
	} // namespace v8

	#undef __