unittests/ExecutionEngine/Orc/RPCUtilsTest.cpp - platform/external/llvm - Git at Google

 //===----------- RPCUtilsTest.cpp - Unit tests the Orc RPC utils ----------===//
 //
 //                     The LLVM Compiler Infrastructure
 //
 // This file is distributed under the University of Illinois Open Source
 // License. See LICENSE.TXT for details.
 //
 //===----------------------------------------------------------------------===//

 #include "llvm/ExecutionEngine/Orc/RPCChannel.h"
 #include "llvm/ExecutionEngine/Orc/RPCUtils.h"
 #include "gtest/gtest.h"

 #include <queue>

 using namespace llvm;
 using namespace llvm::orc;
 using namespace llvm::orc::remote;

 class Queue : public std::queue<char> {
 public:
   std::mutex &getLock() { return Lock; }

 private:
   std::mutex Lock;
 };

 class QueueChannel : public RPCChannel {
 public:
   QueueChannel(Queue &InQueue, Queue &OutQueue)
       : InQueue(InQueue), OutQueue(OutQueue) {}

   Error readBytes(char *Dst, unsigned Size) override {
     while (Size != 0) {
       // If there's nothing to read then yield.
       while (InQueue.empty())
         std::this_thread::yield();

       // Lock the channel and read what we can.
       std::lock_guard<std::mutex> Lock(InQueue.getLock());
       while (!InQueue.empty() && Size) {
         *Dst++ = InQueue.front();
         --Size;
         InQueue.pop();
       }
     }
     return Error::success();
   }

   Error appendBytes(const char *Src, unsigned Size) override {
     std::lock_guard<std::mutex> Lock(OutQueue.getLock());
     while (Size--)
       OutQueue.push(*Src++);
     return Error::success();
   }

   Error send() override { return Error::success(); }

 private:
   Queue &InQueue;
   Queue &OutQueue;
 };

 class DummyRPC : public testing::Test, public RPC<QueueChannel> {
 public:
   enum FuncId : uint32_t {
     VoidBoolId = RPCFunctionIdTraits<FuncId>::FirstValidId,
     IntIntId,
     AllTheTypesId
   };

   typedef Function<VoidBoolId, void(bool)> VoidBool;
   typedef Function<IntIntId, int32_t(int32_t)> IntInt;
   typedef Function<AllTheTypesId,
                    void(int8_t, uint8_t, int16_t, uint16_t, int32_t, uint32_t,
                         int64_t, uint64_t, bool, std::string, std::vector<int>)>
       AllTheTypes;
 };

 TEST_F(DummyRPC, TestAsyncVoidBool) {
   Queue Q1, Q2;
   QueueChannel C1(Q1, Q2);
   QueueChannel C2(Q2, Q1);

   // Make an async call.
   auto ResOrErr = callAsyncWithSeq<VoidBool>(C1, true);
   EXPECT_TRUE(!!ResOrErr) << "Simple call over queue failed";

   {
     // Expect a call to Proc1.
     auto EC = expect<VoidBool>(C2, [&](bool &B) {
       EXPECT_EQ(B, true) << "Bool serialization broken";
       return Error::success();
     });
     EXPECT_FALSE(EC) << "Simple expect over queue failed";
   }

   {
     // Wait for the result.
     auto EC = waitForResult(C1, ResOrErr->second, handleNone);
     EXPECT_FALSE(EC) << "Could not read result.";
   }

   // Verify that the function returned ok.
   auto Val = ResOrErr->first.get();
   EXPECT_TRUE(Val) << "Remote void function failed to execute.";
 }

 TEST_F(DummyRPC, TestAsyncIntInt) {
   Queue Q1, Q2;
   QueueChannel C1(Q1, Q2);
   QueueChannel C2(Q2, Q1);

   // Make an async call.
   auto ResOrErr = callAsyncWithSeq<IntInt>(C1, 21);
   EXPECT_TRUE(!!ResOrErr) << "Simple call over queue failed";

   {
     // Expect a call to Proc1.
     auto EC = expect<IntInt>(C2, [&](int32_t I) -> Expected<int32_t> {
       EXPECT_EQ(I, 21) << "Bool serialization broken";
       return 2 * I;
     });
     EXPECT_FALSE(EC) << "Simple expect over queue failed";
   }

   {
     // Wait for the result.
     auto EC = waitForResult(C1, ResOrErr->second, handleNone);
     EXPECT_FALSE(EC) << "Could not read result.";
   }

   // Verify that the function returned ok.
   auto Val = ResOrErr->first.get();
   EXPECT_TRUE(!!Val) << "Remote int function failed to execute.";
   EXPECT_EQ(*Val, 42) << "Remote int function return wrong value.";
 }

 TEST_F(DummyRPC, TestSerialization) {
   Queue Q1, Q2;
   QueueChannel C1(Q1, Q2);
   QueueChannel C2(Q2, Q1);

   // Make a call to Proc1.
   std::vector<int> v({42, 7});
   auto ResOrErr = callAsyncWithSeq<AllTheTypes>(
       C1, -101, 250, -10000, 10000, -1000000000, 1000000000, -10000000000,
       10000000000, true, "foo", v);
   EXPECT_TRUE(!!ResOrErr) << "Big (serialization test) call over queue failed";

   {
     // Expect a call to Proc1.
     auto EC = expect<AllTheTypes>(
         C2, [&](int8_t &s8, uint8_t &u8, int16_t &s16, uint16_t &u16,
                 int32_t &s32, uint32_t &u32, int64_t &s64, uint64_t &u64,
                 bool &b, std::string &s, std::vector<int> &v) {

           EXPECT_EQ(s8, -101) << "int8_t serialization broken";
           EXPECT_EQ(u8, 250) << "uint8_t serialization broken";
           EXPECT_EQ(s16, -10000) << "int16_t serialization broken";
           EXPECT_EQ(u16, 10000) << "uint16_t serialization broken";
           EXPECT_EQ(s32, -1000000000) << "int32_t serialization broken";
           EXPECT_EQ(u32, 1000000000ULL) << "uint32_t serialization broken";
           EXPECT_EQ(s64, -10000000000) << "int64_t serialization broken";
           EXPECT_EQ(u64, 10000000000ULL) << "uint64_t serialization broken";
           EXPECT_EQ(b, true) << "bool serialization broken";
           EXPECT_EQ(s, "foo") << "std::string serialization broken";
           EXPECT_EQ(v, std::vector<int>({42, 7}))
               << "std::vector serialization broken";
           return Error::success();
         });
     EXPECT_FALSE(EC) << "Big (serialization test) call over queue failed";
   }

   {
     // Wait for the result.
     auto EC = waitForResult(C1, ResOrErr->second, handleNone);
     EXPECT_FALSE(EC) << "Could not read result.";
   }

   // Verify that the function returned ok.
   auto Val = ResOrErr->first.get();
   EXPECT_TRUE(Val) << "Remote void function failed to execute.";
 }

 // Test the synchronous call API.
 // FIXME: Re-enable once deadlock encountered on S390 has been debugged / fixed,
 //        see http://lab.llvm.org:8011/builders/clang-s390x-linux/builds/3459
 // TEST_F(DummyRPC, TestSynchronousCall) {
 //   Queue Q1, Q2;
 //   QueueChannel C1(Q1, Q2);
 //   QueueChannel C2(Q2, Q1);
 //
 //   auto ServerResult =
 //     std::async(std::launch::async,
 //       [&]() {
 //         return expect<IntInt>(C2, [&](int32_t V) { return V; });
 //       });
 //
 //   auto ValOrErr = callST<IntInt>(C1, 42);
 //
 //   EXPECT_FALSE(!!ServerResult.get())
 //     << "Server returned an error.";
 //   EXPECT_TRUE(!!ValOrErr)
 //     << "callST returned an error.";
 //   EXPECT_EQ(*ValOrErr, 42)
 //     << "Incorrect callST<IntInt> result";
 // }
	//===----------- RPCUtilsTest.cpp - Unit tests the Orc RPC utils ----------===//
	//
	// The LLVM Compiler Infrastructure
	//
	// This file is distributed under the University of Illinois Open Source
	// License. See LICENSE.TXT for details.
	//
	//===----------------------------------------------------------------------===//

	#include "llvm/ExecutionEngine/Orc/RPCChannel.h"
	#include "llvm/ExecutionEngine/Orc/RPCUtils.h"
	#include "gtest/gtest.h"

	#include <queue>

	using namespace llvm;
	using namespace llvm::orc;
	using namespace llvm::orc::remote;

	class Queue : public std::queue<char> {
	public:
	std::mutex &getLock() { return Lock; }

	private:
	std::mutex Lock;
	};

	class QueueChannel : public RPCChannel {
	public:
	QueueChannel(Queue &InQueue, Queue &OutQueue)
	: InQueue(InQueue), OutQueue(OutQueue) {}

	Error readBytes(char *Dst, unsigned Size) override {
	while (Size != 0) {
	// If there's nothing to read then yield.
	while (InQueue.empty())
	std::this_thread::yield();

	// Lock the channel and read what we can.
	std::lock_guard<std::mutex> Lock(InQueue.getLock());
	while (!InQueue.empty() && Size) {
	*Dst++ = InQueue.front();
	--Size;
	InQueue.pop();
	}
	}
	return Error::success();
	}

	Error appendBytes(const char *Src, unsigned Size) override {
	std::lock_guard<std::mutex> Lock(OutQueue.getLock());
	while (Size--)
	OutQueue.push(*Src++);
	return Error::success();
	}

	Error send() override { return Error::success(); }

	private:
	Queue &InQueue;
	Queue &OutQueue;
	};

	class DummyRPC : public testing::Test, public RPC<QueueChannel> {
	public:
	enum FuncId : uint32_t {
	VoidBoolId = RPCFunctionIdTraits<FuncId>::FirstValidId,
	IntIntId,
	AllTheTypesId
	};

	typedef Function<VoidBoolId, void(bool)> VoidBool;
	typedef Function<IntIntId, int32_t(int32_t)> IntInt;
	typedef Function<AllTheTypesId,
	void(int8_t, uint8_t, int16_t, uint16_t, int32_t, uint32_t,
	int64_t, uint64_t, bool, std::string, std::vector<int>)>
	AllTheTypes;
	};

	TEST_F(DummyRPC, TestAsyncVoidBool) {
	Queue Q1, Q2;
	QueueChannel C1(Q1, Q2);
	QueueChannel C2(Q2, Q1);

	// Make an async call.
	auto ResOrErr = callAsyncWithSeq<VoidBool>(C1, true);
	EXPECT_TRUE(!!ResOrErr) << "Simple call over queue failed";

	{
	// Expect a call to Proc1.
	auto EC = expect<VoidBool>(C2, [&](bool &B) {
	EXPECT_EQ(B, true) << "Bool serialization broken";
	return Error::success();
	});
	EXPECT_FALSE(EC) << "Simple expect over queue failed";
	}

	{
	// Wait for the result.
	auto EC = waitForResult(C1, ResOrErr->second, handleNone);
	EXPECT_FALSE(EC) << "Could not read result.";
	}

	// Verify that the function returned ok.
	auto Val = ResOrErr->first.get();
	EXPECT_TRUE(Val) << "Remote void function failed to execute.";
	}

	TEST_F(DummyRPC, TestAsyncIntInt) {
	Queue Q1, Q2;
	QueueChannel C1(Q1, Q2);
	QueueChannel C2(Q2, Q1);

	// Make an async call.
	auto ResOrErr = callAsyncWithSeq<IntInt>(C1, 21);
	EXPECT_TRUE(!!ResOrErr) << "Simple call over queue failed";

	{
	// Expect a call to Proc1.
	auto EC = expect<IntInt>(C2, [&](int32_t I) -> Expected<int32_t> {
	EXPECT_EQ(I, 21) << "Bool serialization broken";
	return 2 * I;
	});
	EXPECT_FALSE(EC) << "Simple expect over queue failed";
	}

	{
	// Wait for the result.
	auto EC = waitForResult(C1, ResOrErr->second, handleNone);
	EXPECT_FALSE(EC) << "Could not read result.";
	}

	// Verify that the function returned ok.
	auto Val = ResOrErr->first.get();
	EXPECT_TRUE(!!Val) << "Remote int function failed to execute.";
	EXPECT_EQ(*Val, 42) << "Remote int function return wrong value.";
	}

	TEST_F(DummyRPC, TestSerialization) {
	Queue Q1, Q2;
	QueueChannel C1(Q1, Q2);
	QueueChannel C2(Q2, Q1);

	// Make a call to Proc1.
	std::vector<int> v({42, 7});
	auto ResOrErr = callAsyncWithSeq<AllTheTypes>(
	C1, -101, 250, -10000, 10000, -1000000000, 1000000000, -10000000000,
	10000000000, true, "foo", v);
	EXPECT_TRUE(!!ResOrErr) << "Big (serialization test) call over queue failed";

	{
	// Expect a call to Proc1.
	auto EC = expect<AllTheTypes>(
	C2, [&](int8_t &s8, uint8_t &u8, int16_t &s16, uint16_t &u16,
	int32_t &s32, uint32_t &u32, int64_t &s64, uint64_t &u64,
	bool &b, std::string &s, std::vector<int> &v) {

	EXPECT_EQ(s8, -101) << "int8_t serialization broken";
	EXPECT_EQ(u8, 250) << "uint8_t serialization broken";
	EXPECT_EQ(s16, -10000) << "int16_t serialization broken";
	EXPECT_EQ(u16, 10000) << "uint16_t serialization broken";
	EXPECT_EQ(s32, -1000000000) << "int32_t serialization broken";
	EXPECT_EQ(u32, 1000000000ULL) << "uint32_t serialization broken";
	EXPECT_EQ(s64, -10000000000) << "int64_t serialization broken";
	EXPECT_EQ(u64, 10000000000ULL) << "uint64_t serialization broken";
	EXPECT_EQ(b, true) << "bool serialization broken";
	EXPECT_EQ(s, "foo") << "std::string serialization broken";
	EXPECT_EQ(v, std::vector<int>({42, 7}))
	<< "std::vector serialization broken";
	return Error::success();
	});
	EXPECT_FALSE(EC) << "Big (serialization test) call over queue failed";
	}

	{
	// Wait for the result.
	auto EC = waitForResult(C1, ResOrErr->second, handleNone);
	EXPECT_FALSE(EC) << "Could not read result.";
	}

	// Verify that the function returned ok.
	auto Val = ResOrErr->first.get();
	EXPECT_TRUE(Val) << "Remote void function failed to execute.";
	}

	// Test the synchronous call API.
	// FIXME: Re-enable once deadlock encountered on S390 has been debugged / fixed,
	// see http://lab.llvm.org:8011/builders/clang-s390x-linux/builds/3459
	// TEST_F(DummyRPC, TestSynchronousCall) {
	// Queue Q1, Q2;
	// QueueChannel C1(Q1, Q2);
	// QueueChannel C2(Q2, Q1);
	//
	// auto ServerResult =
	// std::async(std::launch::async,
	// [&]() {
	// return expect<IntInt>(C2, [&](int32_t V) { return V; });
	// });
	//
	// auto ValOrErr = callST<IntInt>(C1, 42);
	//
	// EXPECT_FALSE(!!ServerResult.get())
	// << "Server returned an error.";
	// EXPECT_TRUE(!!ValOrErr)
	// << "callST returned an error.";
	// EXPECT_EQ(*ValOrErr, 42)
	// << "Incorrect callST<IntInt> result";
	// }