src/v8/test/cctest/compiler/test-run-retpoline.cc - cobalt - Git at Google

 // Copyright 2018 the V8 project authors. All rights reserved.
 // Use of this source code is governed by a BSD-style license that can be
 // found in the LICENSE file.

 #include "src/codegen/assembler-inl.h"
 #include "src/codegen/code-stub-assembler.h"
 #include "src/codegen/macro-assembler.h"

 #include "test/cctest/cctest.h"
 #include "test/cctest/compiler/code-assembler-tester.h"
 #include "test/cctest/compiler/function-tester.h"

 namespace v8 {
 namespace internal {
 namespace compiler {
 namespace test_run_retpoline {

 #define __ assembler.

 namespace {

 // Function that takes a number of pointer-sized integer arguments, calculates a
 // weighted sum of them and returns it.
 Handle<Code> BuildCallee(Isolate* isolate, CallDescriptor* call_descriptor) {
   CodeAssemblerTester tester(isolate, call_descriptor, "callee");
   CodeStubAssembler assembler(tester.state());
   int param_count = static_cast<int>(call_descriptor->StackParameterCount());
   Node* sum = __ IntPtrConstant(0);
   for (int i = 0; i < param_count; ++i) {
     Node* product = __ IntPtrMul(__ Parameter(i), __ IntPtrConstant(i + 1));
     sum = __ IntPtrAdd(sum, product);
   }
   __ Return(sum);
   return tester.GenerateCodeCloseAndEscape();
 }

 // Function that tail-calls another function with a number of pointer-sized
 // integer arguments.
 Handle<Code> BuildCaller(Isolate* isolate, CallDescriptor* call_descriptor,
                          CallDescriptor* callee_descriptor, bool tail) {
   CodeAssemblerTester tester(isolate, call_descriptor, "caller");
   CodeStubAssembler assembler(tester.state());
   std::vector<Node*> params;
   // The first parameter is always the callee.
   Handle<Code> callee = BuildCallee(isolate, callee_descriptor);
   // defeat the instruction selector.
   CodeStubAssembler::Variable target_var(&assembler,
                                          MachineRepresentation::kTagged);
   CodeStubAssembler::Label t(&assembler), f(&assembler),
       end(&assembler, &target_var);
   __ Branch(__ Int32Constant(0), &t, &f);
   __ BIND(&t);
   target_var.Bind(__ HeapConstant(callee));
   __ Goto(&end);
   __ BIND(&f);
   target_var.Bind(__ HeapConstant(callee));
   __ Goto(&end);
   __ BIND(&end);
   params.push_back(target_var.value());

   int param_count = static_cast<int>(callee_descriptor->StackParameterCount());
   for (int i = 0; i < param_count; ++i) {
     params.push_back(__ IntPtrConstant(i));
   }
   DCHECK_EQ(param_count + 1, params.size());
   if (tail) {
     tester.raw_assembler_for_testing()->TailCallN(
         callee_descriptor, param_count + 1, params.data());
   } else {
     Node* result = tester.raw_assembler_for_testing()->CallN(
         callee_descriptor, param_count + 1, params.data());
     __ Return(result);
   }
   return tester.GenerateCodeCloseAndEscape();
 }

 // Setup function, which calls "caller".
 Handle<Code> BuildSetupFunction(Isolate* isolate,
                                 CallDescriptor* caller_descriptor,
                                 CallDescriptor* callee_descriptor, bool tail) {
   CodeAssemblerTester tester(isolate, 0);
   CodeStubAssembler assembler(tester.state());
   std::vector<Node*> params;
   // The first parameter is always the callee.
   params.push_back(__ HeapConstant(
       BuildCaller(isolate, caller_descriptor, callee_descriptor, tail)));
   // Set up arguments for "Caller".
   int param_count = static_cast<int>(caller_descriptor->StackParameterCount());
   for (int i = 0; i < param_count; ++i) {
     // Use values that are different from the ones we will pass to this
     // function's callee later.
     params.push_back(__ IntPtrConstant(i + 42));
   }
   DCHECK_EQ(param_count + 1, params.size());
   Node* raw_result = tester.raw_assembler_for_testing()->CallN(
       caller_descriptor, param_count + 1, params.data());
   __ Return(__ SmiTag(raw_result));
   return tester.GenerateCodeCloseAndEscape();
 }

 CallDescriptor* CreateDescriptorForStackArguments(Zone* zone,
                                                   int stack_param_count) {
   LocationSignature::Builder locations(zone, 1,
                                        static_cast<size_t>(stack_param_count));

   locations.AddReturn(LinkageLocation::ForRegister(kReturnRegister0.code(),
                                                    MachineType::IntPtr()));

   for (int i = 0; i < stack_param_count; ++i) {
     locations.AddParam(LinkageLocation::ForCallerFrameSlot(
         i - stack_param_count, MachineType::IntPtr()));
   }

   return new (zone)
       CallDescriptor(CallDescriptor::kCallCodeObject,  // kind
                      MachineType::AnyTagged(),         // target MachineType
                      LinkageLocation::ForAnyRegister(
                          MachineType::AnyTagged()),  // target location
                      locations.Build(),              // location_sig
                      stack_param_count,              // stack_parameter_count
                      Operator::kNoProperties,        // properties
                      kNoCalleeSaved,                 // callee-saved registers
                      kNoCalleeSaved,                 // callee-saved fp
                      CallDescriptor::kRetpoline);    // flags
 }

 // Test a tail call from a caller with n parameters to a callee with m
 // parameters. All parameters are pointer-sized.
 void TestHelper(int n, int m, bool tail) {
   HandleAndZoneScope scope;
   Isolate* isolate = scope.main_isolate();
   CanonicalHandleScope canonical(isolate);
   Zone* zone = scope.main_zone();
   CallDescriptor* caller_descriptor =
       CreateDescriptorForStackArguments(zone, n);
   CallDescriptor* callee_descriptor =
       CreateDescriptorForStackArguments(zone, m);
   Handle<Code> setup =
       BuildSetupFunction(isolate, caller_descriptor, callee_descriptor, tail);
   FunctionTester ft(setup, 0);
   Handle<Object> result = ft.Call().ToHandleChecked();
   int expected = 0;
   for (int i = 0; i < m; ++i) expected += (i + 1) * i;
   CHECK_EQ(expected, Handle<Smi>::cast(result)->value());
 }

 }  // namespace

 #undef __

 TEST(RetpolineOddEven) {
   TestHelper(1, 0, false);
   TestHelper(1, 2, false);
   TestHelper(3, 2, false);
   TestHelper(3, 4, false);
 }

 TEST(RetpolineOddEvenTail) {
   TestHelper(1, 0, true);
   TestHelper(1, 2, true);
   TestHelper(3, 2, true);
   TestHelper(3, 4, true);
 }

 TEST(RetpolineOddOdd) {
   TestHelper(1, 1, false);
   TestHelper(1, 3, false);
   TestHelper(3, 1, false);
   TestHelper(3, 3, false);
 }

 TEST(RetpolineOddOddTail) {
   TestHelper(1, 1, true);
   TestHelper(1, 3, true);
   TestHelper(3, 1, true);
   TestHelper(3, 3, true);
 }

 TEST(RetpolineEvenEven) {
   TestHelper(0, 0, false);
   TestHelper(0, 2, false);
   TestHelper(2, 0, false);
   TestHelper(2, 2, false);
 }

 TEST(RetpolineEvenEvenTail) {
   TestHelper(0, 0, true);
   TestHelper(0, 2, true);
   TestHelper(2, 0, true);
   TestHelper(2, 2, true);
 }

 TEST(RetpolineEvenOdd) {
   TestHelper(0, 1, false);
   TestHelper(0, 3, false);
   TestHelper(2, 1, false);
   TestHelper(2, 3, false);
 }

 TEST(RetpolineEvenOddTail) {
   TestHelper(0, 1, true);
   TestHelper(0, 3, true);
   TestHelper(2, 1, true);
   TestHelper(2, 3, true);
 }

 }  // namespace test_run_retpoline
 }  // namespace compiler
 }  // namespace internal
 }  // namespace v8
	// Copyright 2018 the V8 project authors. All rights reserved.
	// Use of this source code is governed by a BSD-style license that can be
	// found in the LICENSE file.

	#include "src/codegen/assembler-inl.h"
	#include "src/codegen/code-stub-assembler.h"
	#include "src/codegen/macro-assembler.h"

	#include "test/cctest/cctest.h"
	#include "test/cctest/compiler/code-assembler-tester.h"
	#include "test/cctest/compiler/function-tester.h"

	namespace v8 {
	namespace internal {
	namespace compiler {
	namespace test_run_retpoline {

	#define __ assembler.

	namespace {

	// Function that takes a number of pointer-sized integer arguments, calculates a
	// weighted sum of them and returns it.
	Handle<Code> BuildCallee(Isolate* isolate, CallDescriptor* call_descriptor) {
	CodeAssemblerTester tester(isolate, call_descriptor, "callee");
	CodeStubAssembler assembler(tester.state());
	int param_count = static_cast<int>(call_descriptor->StackParameterCount());
	Node* sum = __ IntPtrConstant(0);
	for (int i = 0; i < param_count; ++i) {
	Node* product = __ IntPtrMul(__ Parameter(i), __ IntPtrConstant(i + 1));
	sum = __ IntPtrAdd(sum, product);
	}
	__ Return(sum);
	return tester.GenerateCodeCloseAndEscape();
	}

	// Function that tail-calls another function with a number of pointer-sized
	// integer arguments.
	Handle<Code> BuildCaller(Isolate* isolate, CallDescriptor* call_descriptor,
	CallDescriptor* callee_descriptor, bool tail) {
	CodeAssemblerTester tester(isolate, call_descriptor, "caller");
	CodeStubAssembler assembler(tester.state());
	std::vector<Node*> params;
	// The first parameter is always the callee.
	Handle<Code> callee = BuildCallee(isolate, callee_descriptor);
	// defeat the instruction selector.
	CodeStubAssembler::Variable target_var(&assembler,
	MachineRepresentation::kTagged);
	CodeStubAssembler::Label t(&assembler), f(&assembler),
	end(&assembler, &target_var);
	__ Branch(__ Int32Constant(0), &t, &f);
	__ BIND(&t);
	target_var.Bind(__ HeapConstant(callee));
	__ Goto(&end);
	__ BIND(&f);
	target_var.Bind(__ HeapConstant(callee));
	__ Goto(&end);
	__ BIND(&end);
	params.push_back(target_var.value());

	int param_count = static_cast<int>(callee_descriptor->StackParameterCount());
	for (int i = 0; i < param_count; ++i) {
	params.push_back(__ IntPtrConstant(i));
	}
	DCHECK_EQ(param_count + 1, params.size());
	if (tail) {
	tester.raw_assembler_for_testing()->TailCallN(
	callee_descriptor, param_count + 1, params.data());
	} else {
	Node* result = tester.raw_assembler_for_testing()->CallN(
	callee_descriptor, param_count + 1, params.data());
	__ Return(result);
	}
	return tester.GenerateCodeCloseAndEscape();
	}

	// Setup function, which calls "caller".
	Handle<Code> BuildSetupFunction(Isolate* isolate,
	CallDescriptor* caller_descriptor,
	CallDescriptor* callee_descriptor, bool tail) {
	CodeAssemblerTester tester(isolate, 0);
	CodeStubAssembler assembler(tester.state());
	std::vector<Node*> params;
	// The first parameter is always the callee.
	params.push_back(__ HeapConstant(
	BuildCaller(isolate, caller_descriptor, callee_descriptor, tail)));
	// Set up arguments for "Caller".
	int param_count = static_cast<int>(caller_descriptor->StackParameterCount());
	for (int i = 0; i < param_count; ++i) {
	// Use values that are different from the ones we will pass to this
	// function's callee later.
	params.push_back(__ IntPtrConstant(i + 42));
	}
	DCHECK_EQ(param_count + 1, params.size());
	Node* raw_result = tester.raw_assembler_for_testing()->CallN(
	caller_descriptor, param_count + 1, params.data());
	__ Return(__ SmiTag(raw_result));
	return tester.GenerateCodeCloseAndEscape();
	}

	CallDescriptor* CreateDescriptorForStackArguments(Zone* zone,
	int stack_param_count) {
	LocationSignature::Builder locations(zone, 1,
	static_cast<size_t>(stack_param_count));

	locations.AddReturn(LinkageLocation::ForRegister(kReturnRegister0.code(),
	MachineType::IntPtr()));

	for (int i = 0; i < stack_param_count; ++i) {
	locations.AddParam(LinkageLocation::ForCallerFrameSlot(
	i - stack_param_count, MachineType::IntPtr()));
	}

	return new (zone)
	CallDescriptor(CallDescriptor::kCallCodeObject, // kind
	MachineType::AnyTagged(), // target MachineType
	LinkageLocation::ForAnyRegister(
	MachineType::AnyTagged()), // target location
	locations.Build(), // location_sig
	stack_param_count, // stack_parameter_count
	Operator::kNoProperties, // properties
	kNoCalleeSaved, // callee-saved registers
	kNoCalleeSaved, // callee-saved fp
	CallDescriptor::kRetpoline); // flags
	}

	// Test a tail call from a caller with n parameters to a callee with m
	// parameters. All parameters are pointer-sized.
	void TestHelper(int n, int m, bool tail) {
	HandleAndZoneScope scope;
	Isolate* isolate = scope.main_isolate();
	CanonicalHandleScope canonical(isolate);
	Zone* zone = scope.main_zone();
	CallDescriptor* caller_descriptor =
	CreateDescriptorForStackArguments(zone, n);
	CallDescriptor* callee_descriptor =
	CreateDescriptorForStackArguments(zone, m);
	Handle<Code> setup =
	BuildSetupFunction(isolate, caller_descriptor, callee_descriptor, tail);
	FunctionTester ft(setup, 0);
	Handle<Object> result = ft.Call().ToHandleChecked();
	int expected = 0;
	for (int i = 0; i < m; ++i) expected += (i + 1) * i;
	CHECK_EQ(expected, Handle<Smi>::cast(result)->value());
	}

	} // namespace

	#undef __

	TEST(RetpolineOddEven) {
	TestHelper(1, 0, false);
	TestHelper(1, 2, false);
	TestHelper(3, 2, false);
	TestHelper(3, 4, false);
	}

	TEST(RetpolineOddEvenTail) {
	TestHelper(1, 0, true);
	TestHelper(1, 2, true);
	TestHelper(3, 2, true);
	TestHelper(3, 4, true);
	}

	TEST(RetpolineOddOdd) {
	TestHelper(1, 1, false);
	TestHelper(1, 3, false);
	TestHelper(3, 1, false);
	TestHelper(3, 3, false);
	}

	TEST(RetpolineOddOddTail) {
	TestHelper(1, 1, true);
	TestHelper(1, 3, true);
	TestHelper(3, 1, true);
	TestHelper(3, 3, true);
	}

	TEST(RetpolineEvenEven) {
	TestHelper(0, 0, false);
	TestHelper(0, 2, false);
	TestHelper(2, 0, false);
	TestHelper(2, 2, false);
	}

	TEST(RetpolineEvenEvenTail) {
	TestHelper(0, 0, true);
	TestHelper(0, 2, true);
	TestHelper(2, 0, true);
	TestHelper(2, 2, true);
	}

	TEST(RetpolineEvenOdd) {
	TestHelper(0, 1, false);
	TestHelper(0, 3, false);
	TestHelper(2, 1, false);
	TestHelper(2, 3, false);
	}

	TEST(RetpolineEvenOddTail) {
	TestHelper(0, 1, true);
	TestHelper(0, 3, true);
	TestHelper(2, 1, true);
	TestHelper(2, 3, true);
	}

	} // namespace test_run_retpoline
	} // namespace compiler
	} // namespace internal
	} // namespace v8