test/cctest/wasm/test-c-wasm-entry.cc - v8/v8 - Git at Google

 // Copyright 2017 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 <cstdint>

 #include "src/assembler-inl.h"
 #include "src/base/overflowing-math.h"
 #include "src/objects-inl.h"
 #include "src/wasm/wasm-objects.h"
 #include "test/cctest/cctest.h"
 #include "test/cctest/compiler/value-helper.h"
 #include "test/cctest/wasm/wasm-run-utils.h"
 #include "test/common/wasm/wasm-macro-gen.h"

 namespace v8 {
 namespace internal {
 namespace wasm {

 /**
  * We test the interface from C to compiled wasm code by generating a wasm
  * function, creating a corresponding signature, compiling the c wasm entry for
  * that signature, and then calling that entry using different test values.
  * The result is compared against the expected result, computed from a lambda
  * passed to the CWasmEntryArgTester.
  */
 namespace {

 template <typename ReturnType, typename... Args>
 class CWasmEntryArgTester {
  public:
   CWasmEntryArgTester(std::initializer_list<uint8_t> wasm_function_bytes,
                       std::function<ReturnType(Args...)> expected_fn)
       : runner_(ExecutionTier::kOptimized),
         isolate_(runner_.main_isolate()),
         expected_fn_(expected_fn),
         sig_(runner_.template CreateSig<ReturnType, Args...>()) {
     std::vector<uint8_t> code{wasm_function_bytes};
     runner_.Build(code.data(), code.data() + code.size());
     wasm_code_ = runner_.builder().GetFunctionCode(0);
     Handle<WasmInstanceObject> instance(runner_.builder().instance_object());
     Handle<WasmDebugInfo> debug_info =
         WasmInstanceObject::GetOrCreateDebugInfo(instance);
     c_wasm_entry_fn_ = WasmDebugInfo::GetCWasmEntry(debug_info, sig_);
   }

   template <typename... Rest>
   void WriteToBuffer(Address buf, Rest... rest) {
     static_assert(sizeof...(rest) == 0, "this is the base case");
   }

   template <typename First, typename... Rest>
   void WriteToBuffer(Address buf, First first, Rest... rest) {
     WriteUnalignedValue(buf, first);
     WriteToBuffer(buf + sizeof(first), rest...);
   }

   void CheckCall(Args... args) {
     std::vector<uint8_t> arg_buffer(sizeof...(args) * 8);
     WriteToBuffer(reinterpret_cast<Address>(arg_buffer.data()), args...);

     Handle<Object> receiver = isolate_->factory()->undefined_value();
     Handle<Object> buffer_obj(
         Object(reinterpret_cast<Address>(arg_buffer.data())), isolate_);
     CHECK(!buffer_obj->IsHeapObject());
     Handle<Object> code_entry_obj(Object(wasm_code_->instruction_start()),
                                   isolate_);
     CHECK(!code_entry_obj->IsHeapObject());
     Handle<Object> call_args[]{code_entry_obj,
                                runner_.builder().instance_object(), buffer_obj};
     static_assert(
         arraysize(call_args) == compiler::CWasmEntryParameters::kNumParameters,
         "adapt this test");
     wasm_code_->native_module()->SetExecutable(true);
     MaybeHandle<Object> return_obj = Execution::Call(
         isolate_, c_wasm_entry_fn_, receiver, arraysize(call_args), call_args);
     CHECK(!return_obj.is_null());
     CHECK(return_obj.ToHandleChecked()->IsSmi());
     CHECK_EQ(0, Smi::ToInt(*return_obj.ToHandleChecked()));

     // Check the result.
     ReturnType result = ReadUnalignedValue<ReturnType>(
         reinterpret_cast<Address>(arg_buffer.data()));
     ReturnType expected = expected_fn_(args...);
     if (std::is_floating_point<ReturnType>::value) {
       CHECK_DOUBLE_EQ(expected, result);
     } else {
       CHECK_EQ(expected, result);
     }
   }

  private:
   WasmRunner<ReturnType, Args...> runner_;
   Isolate* isolate_;
   std::function<ReturnType(Args...)> expected_fn_;
   FunctionSig* sig_;
   Handle<JSFunction> c_wasm_entry_fn_;
   WasmCode* wasm_code_;
 };

 }  // namespace

 // Pass int32_t, return int32_t.
 TEST(TestCWasmEntryArgPassing_int32) {
   CWasmEntryArgTester<int32_t, int32_t> tester(
       {// Return 2*<0> + 1.
        WASM_I32_ADD(WASM_I32_MUL(WASM_I32V_1(2), WASM_GET_LOCAL(0)), WASM_ONE)},
       [](int32_t a) {
         return base::AddWithWraparound(base::MulWithWraparound(2, a), 1);
       });

   FOR_INT32_INPUTS(v) { tester.CheckCall(v); }
 }

 // Pass int64_t, return double.
 TEST(TestCWasmEntryArgPassing_double_int64) {
   CWasmEntryArgTester<double, int64_t> tester(
       {// Return (double)<0>.
        WASM_F64_SCONVERT_I64(WASM_GET_LOCAL(0))},
       [](int64_t a) { return static_cast<double>(a); });

   FOR_INT64_INPUTS(v) { tester.CheckCall(v); }
 }

 // Pass double, return int64_t.
 TEST(TestCWasmEntryArgPassing_int64_double) {
   CWasmEntryArgTester<int64_t, double> tester(
       {// Return (int64_t)<0>.
        WASM_I64_SCONVERT_F64(WASM_GET_LOCAL(0))},
       [](double d) { return static_cast<int64_t>(d); });

   FOR_INT64_INPUTS(i) { tester.CheckCall(i); }
 }

 // Pass float, return double.
 TEST(TestCWasmEntryArgPassing_float_double) {
   CWasmEntryArgTester<double, float> tester(
       {// Return 2*(double)<0> + 1.
        WASM_F64_ADD(
            WASM_F64_MUL(WASM_F64(2), WASM_F64_CONVERT_F32(WASM_GET_LOCAL(0))),
            WASM_F64(1))},
       [](float f) { return 2. * static_cast<double>(f) + 1.; });

   FOR_FLOAT32_INPUTS(f) { tester.CheckCall(f); }
 }

 // Pass two doubles, return double.
 TEST(TestCWasmEntryArgPassing_double_double) {
   CWasmEntryArgTester<double, double, double> tester(
       {// Return <0> + <1>.
        WASM_F64_ADD(WASM_GET_LOCAL(0), WASM_GET_LOCAL(1))},
       [](double a, double b) { return a + b; });

   FOR_FLOAT64_INPUTS(d1) {
     FOR_FLOAT64_INPUTS(d2) { tester.CheckCall(d1, d2); }
   }
 }

 // Pass int32_t, int64_t, float and double, return double.
 TEST(TestCWasmEntryArgPassing_AllTypes) {
   CWasmEntryArgTester<double, int32_t, int64_t, float, double> tester(
       {
           // Convert all arguments to double, add them and return the sum.
           WASM_F64_ADD(          // <0+1+2> + <3>
               WASM_F64_ADD(      // <0+1> + <2>
                   WASM_F64_ADD(  // <0> + <1>
                       WASM_F64_SCONVERT_I32(
                           WASM_GET_LOCAL(0)),  // <0> to double
                       WASM_F64_SCONVERT_I64(
                           WASM_GET_LOCAL(1))),               // <1> to double
                   WASM_F64_CONVERT_F32(WASM_GET_LOCAL(2))),  // <2> to double
               WASM_GET_LOCAL(3))                             // <3>
       },
       [](int32_t a, int64_t b, float c, double d) {
         return 0. + a + b + c + d;
       });

   Vector<const int32_t> test_values_i32 = compiler::ValueHelper::int32_vector();
   Vector<const int64_t> test_values_i64 = compiler::ValueHelper::int64_vector();
   Vector<const float> test_values_f32 = compiler::ValueHelper::float32_vector();
   Vector<const double> test_values_f64 =
       compiler::ValueHelper::float64_vector();
   size_t max_len =
       std::max(std::max(test_values_i32.size(), test_values_i64.size()),
                std::max(test_values_f32.size(), test_values_f64.size()));
   for (size_t i = 0; i < max_len; ++i) {
     int32_t i32 = test_values_i32[i % test_values_i32.size()];
     int64_t i64 = test_values_i64[i % test_values_i64.size()];
     float f32 = test_values_f32[i % test_values_f32.size()];
     double f64 = test_values_f64[i % test_values_f64.size()];
     tester.CheckCall(i32, i64, f32, f64);
   }
 }

 }  // namespace wasm
 }  // namespace internal
 }  // namespace v8
	// Copyright 2017 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 <cstdint>

	#include "src/assembler-inl.h"
	#include "src/base/overflowing-math.h"
	#include "src/objects-inl.h"
	#include "src/wasm/wasm-objects.h"
	#include "test/cctest/cctest.h"
	#include "test/cctest/compiler/value-helper.h"
	#include "test/cctest/wasm/wasm-run-utils.h"
	#include "test/common/wasm/wasm-macro-gen.h"

	namespace v8 {
	namespace internal {
	namespace wasm {

	/**
	* We test the interface from C to compiled wasm code by generating a wasm
	* function, creating a corresponding signature, compiling the c wasm entry for
	* that signature, and then calling that entry using different test values.
	* The result is compared against the expected result, computed from a lambda
	* passed to the CWasmEntryArgTester.
	*/
	namespace {

	template <typename ReturnType, typename... Args>
	class CWasmEntryArgTester {
	public:
	CWasmEntryArgTester(std::initializer_list<uint8_t> wasm_function_bytes,
	std::function<ReturnType(Args...)> expected_fn)
	: runner_(ExecutionTier::kOptimized),
	isolate_(runner_.main_isolate()),
	expected_fn_(expected_fn),
	sig_(runner_.template CreateSig<ReturnType, Args...>()) {
	std::vector<uint8_t> code{wasm_function_bytes};
	runner_.Build(code.data(), code.data() + code.size());
	wasm_code_ = runner_.builder().GetFunctionCode(0);
	Handle<WasmInstanceObject> instance(runner_.builder().instance_object());
	Handle<WasmDebugInfo> debug_info =
	WasmInstanceObject::GetOrCreateDebugInfo(instance);
	c_wasm_entry_fn_ = WasmDebugInfo::GetCWasmEntry(debug_info, sig_);
	}

	template <typename... Rest>
	void WriteToBuffer(Address buf, Rest... rest) {
	static_assert(sizeof...(rest) == 0, "this is the base case");
	}

	template <typename First, typename... Rest>
	void WriteToBuffer(Address buf, First first, Rest... rest) {
	WriteUnalignedValue(buf, first);
	WriteToBuffer(buf + sizeof(first), rest...);
	}

	void CheckCall(Args... args) {
	std::vector<uint8_t> arg_buffer(sizeof...(args) * 8);
	WriteToBuffer(reinterpret_cast<Address>(arg_buffer.data()), args...);

	Handle<Object> receiver = isolate_->factory()->undefined_value();
	Handle<Object> buffer_obj(
	Object(reinterpret_cast<Address>(arg_buffer.data())), isolate_);
	CHECK(!buffer_obj->IsHeapObject());
	Handle<Object> code_entry_obj(Object(wasm_code_->instruction_start()),
	isolate_);
	CHECK(!code_entry_obj->IsHeapObject());
	Handle<Object> call_args[]{code_entry_obj,
	runner_.builder().instance_object(), buffer_obj};
	static_assert(
	arraysize(call_args) == compiler::CWasmEntryParameters::kNumParameters,
	"adapt this test");
	wasm_code_->native_module()->SetExecutable(true);
	MaybeHandle<Object> return_obj = Execution::Call(
	isolate_, c_wasm_entry_fn_, receiver, arraysize(call_args), call_args);
	CHECK(!return_obj.is_null());
	CHECK(return_obj.ToHandleChecked()->IsSmi());
	CHECK_EQ(0, Smi::ToInt(*return_obj.ToHandleChecked()));

	// Check the result.
	ReturnType result = ReadUnalignedValue<ReturnType>(
	reinterpret_cast<Address>(arg_buffer.data()));
	ReturnType expected = expected_fn_(args...);
	if (std::is_floating_point<ReturnType>::value) {
	CHECK_DOUBLE_EQ(expected, result);
	} else {
	CHECK_EQ(expected, result);
	}
	}

	private:
	WasmRunner<ReturnType, Args...> runner_;
	Isolate* isolate_;
	std::function<ReturnType(Args...)> expected_fn_;
	FunctionSig* sig_;
	Handle<JSFunction> c_wasm_entry_fn_;
	WasmCode* wasm_code_;
	};

	} // namespace

	// Pass int32_t, return int32_t.
	TEST(TestCWasmEntryArgPassing_int32) {
	CWasmEntryArgTester<int32_t, int32_t> tester(
	{// Return 2*<0> + 1.
	WASM_I32_ADD(WASM_I32_MUL(WASM_I32V_1(2), WASM_GET_LOCAL(0)), WASM_ONE)},
	[](int32_t a) {
	return base::AddWithWraparound(base::MulWithWraparound(2, a), 1);
	});

	FOR_INT32_INPUTS(v) { tester.CheckCall(v); }
	}

	// Pass int64_t, return double.
	TEST(TestCWasmEntryArgPassing_double_int64) {
	CWasmEntryArgTester<double, int64_t> tester(
	{// Return (double)<0>.
	WASM_F64_SCONVERT_I64(WASM_GET_LOCAL(0))},
	[](int64_t a) { return static_cast<double>(a); });

	FOR_INT64_INPUTS(v) { tester.CheckCall(v); }
	}

	// Pass double, return int64_t.
	TEST(TestCWasmEntryArgPassing_int64_double) {
	CWasmEntryArgTester<int64_t, double> tester(
	{// Return (int64_t)<0>.
	WASM_I64_SCONVERT_F64(WASM_GET_LOCAL(0))},
	[](double d) { return static_cast<int64_t>(d); });

	FOR_INT64_INPUTS(i) { tester.CheckCall(i); }
	}

	// Pass float, return double.
	TEST(TestCWasmEntryArgPassing_float_double) {
	CWasmEntryArgTester<double, float> tester(
	{// Return 2*(double)<0> + 1.
	WASM_F64_ADD(
	WASM_F64_MUL(WASM_F64(2), WASM_F64_CONVERT_F32(WASM_GET_LOCAL(0))),
	WASM_F64(1))},
	[](float f) { return 2. * static_cast<double>(f) + 1.; });

	FOR_FLOAT32_INPUTS(f) { tester.CheckCall(f); }
	}

	// Pass two doubles, return double.
	TEST(TestCWasmEntryArgPassing_double_double) {
	CWasmEntryArgTester<double, double, double> tester(
	{// Return <0> + <1>.
	WASM_F64_ADD(WASM_GET_LOCAL(0), WASM_GET_LOCAL(1))},
	[](double a, double b) { return a + b; });

	FOR_FLOAT64_INPUTS(d1) {
	FOR_FLOAT64_INPUTS(d2) { tester.CheckCall(d1, d2); }
	}
	}

	// Pass int32_t, int64_t, float and double, return double.
	TEST(TestCWasmEntryArgPassing_AllTypes) {
	CWasmEntryArgTester<double, int32_t, int64_t, float, double> tester(
	{
	// Convert all arguments to double, add them and return the sum.
	WASM_F64_ADD( // <0+1+2> + <3>
	WASM_F64_ADD( // <0+1> + <2>
	WASM_F64_ADD( // <0> + <1>
	WASM_F64_SCONVERT_I32(
	WASM_GET_LOCAL(0)), // <0> to double
	WASM_F64_SCONVERT_I64(
	WASM_GET_LOCAL(1))), // <1> to double
	WASM_F64_CONVERT_F32(WASM_GET_LOCAL(2))), // <2> to double
	WASM_GET_LOCAL(3)) // <3>
	},
	[](int32_t a, int64_t b, float c, double d) {
	return 0. + a + b + c + d;
	});

	Vector<const int32_t> test_values_i32 = compiler::ValueHelper::int32_vector();
	Vector<const int64_t> test_values_i64 = compiler::ValueHelper::int64_vector();
	Vector<const float> test_values_f32 = compiler::ValueHelper::float32_vector();
	Vector<const double> test_values_f64 =
	compiler::ValueHelper::float64_vector();
	size_t max_len =
	std::max(std::max(test_values_i32.size(), test_values_i64.size()),
	std::max(test_values_f32.size(), test_values_f64.size()));
	for (size_t i = 0; i < max_len; ++i) {
	int32_t i32 = test_values_i32[i % test_values_i32.size()];
	int64_t i64 = test_values_i64[i % test_values_i64.size()];
	float f32 = test_values_f32[i % test_values_f32.size()];
	double f64 = test_values_f64[i % test_values_f64.size()];
	tester.CheckCall(i32, i64, f32, f64);
	}
	}

	} // namespace wasm
	} // namespace internal
	} // namespace v8