//===- MCJITMultipeModuleTest.cpp - Unit tests for the MCJIT ----*- C++ -*-===// // // The LLVM Compiler Infrastructure // // This file is distributed under the University of Illinois Open Source // License. See LICENSE.TXT for details. // //===----------------------------------------------------------------------===// // // This test suite verifies MCJIT for handling multiple modules in a single // ExecutionEngine by building multiple modules, making function calls across // modules, accessing global variables, etc. //===----------------------------------------------------------------------===// #include "llvm/ExecutionEngine/MCJIT.h" #include "MCJITTestBase.h" #include "gtest/gtest.h" using namespace llvm; namespace { class MCJITMultipleModuleTest : public testing::Test, public MCJITTestBase {}; // FIXME: ExecutionEngine has no support empty modules /* TEST_F(MCJITMultipleModuleTest, multiple_empty_modules) { SKIP_UNSUPPORTED_PLATFORM; createJIT(M.take()); // JIT-compile EXPECT_NE(0, TheJIT->getObjectImage()) << "Unable to generate executable loaded object image"; TheJIT->addModule(createEmptyModule("<other module>")); TheJIT->addModule(createEmptyModule("<other other module>")); // JIT again EXPECT_NE(0, TheJIT->getObjectImage()) << "Unable to generate executable loaded object image"; } */ // Helper Function to test add operation void checkAdd(uint64_t ptr) { ASSERT_TRUE(ptr != 0) << "Unable to get pointer to function."; int (*AddPtr)(int, int) = (int (*)(int, int))ptr; EXPECT_EQ(0, AddPtr(0, 0)); EXPECT_EQ(1, AddPtr(1, 0)); EXPECT_EQ(3, AddPtr(1, 2)); EXPECT_EQ(-5, AddPtr(-2, -3)); EXPECT_EQ(30, AddPtr(10, 20)); EXPECT_EQ(-30, AddPtr(-10, -20)); EXPECT_EQ(-40, AddPtr(-10, -30)); } void checkAccumulate(uint64_t ptr) { ASSERT_TRUE(ptr != 0) << "Unable to get pointer to function."; int32_t (*FPtr)(int32_t) = (int32_t (*)(int32_t))(intptr_t)ptr; EXPECT_EQ(0, FPtr(0)); EXPECT_EQ(1, FPtr(1)); EXPECT_EQ(3, FPtr(2)); EXPECT_EQ(6, FPtr(3)); EXPECT_EQ(10, FPtr(4)); EXPECT_EQ(15, FPtr(5)); } // FIXME: ExecutionEngine has no support empty modules /* TEST_F(MCJITMultipleModuleTest, multiple_empty_modules) { SKIP_UNSUPPORTED_PLATFORM; createJIT(M.take()); // JIT-compile EXPECT_NE(0, TheJIT->getObjectImage()) << "Unable to generate executable loaded object image"; TheJIT->addModule(createEmptyModule("<other module>")); TheJIT->addModule(createEmptyModule("<other other module>")); // JIT again EXPECT_NE(0, TheJIT->getObjectImage()) << "Unable to generate executable loaded object image"; } */ // Module A { Function FA }, // Module B { Function FB }, // execute FA then FB TEST_F(MCJITMultipleModuleTest, two_module_case) { SKIP_UNSUPPORTED_PLATFORM; std::unique_ptr<Module> A, B; Function *FA, *FB; createTwoModuleCase(A, FA, B, FB); createJIT(std::move(A)); TheJIT->addModule(std::move(B)); uint64_t ptr = TheJIT->getFunctionAddress(FA->getName().str()); checkAdd(ptr); ptr = TheJIT->getFunctionAddress(FB->getName().str()); checkAdd(ptr); } // Module A { Function FA }, // Module B { Function FB }, // execute FB then FA TEST_F(MCJITMultipleModuleTest, two_module_reverse_case) { SKIP_UNSUPPORTED_PLATFORM; std::unique_ptr<Module> A, B; Function *FA, *FB; createTwoModuleCase(A, FA, B, FB); createJIT(std::move(A)); TheJIT->addModule(std::move(B)); uint64_t ptr = TheJIT->getFunctionAddress(FB->getName().str()); TheJIT->finalizeObject(); checkAdd(ptr); ptr = TheJIT->getFunctionAddress(FA->getName().str()); checkAdd(ptr); } // Module A { Function FA }, // Module B { Extern FA, Function FB which calls FA }, // execute FB then FA TEST_F(MCJITMultipleModuleTest, two_module_extern_reverse_case) { SKIP_UNSUPPORTED_PLATFORM; std::unique_ptr<Module> A, B; Function *FA, *FB; createTwoModuleExternCase(A, FA, B, FB); createJIT(std::move(A)); TheJIT->addModule(std::move(B)); uint64_t ptr = TheJIT->getFunctionAddress(FB->getName().str()); TheJIT->finalizeObject(); checkAdd(ptr); ptr = TheJIT->getFunctionAddress(FA->getName().str()); checkAdd(ptr); } // Module A { Function FA }, // Module B { Extern FA, Function FB which calls FA }, // execute FA then FB TEST_F(MCJITMultipleModuleTest, two_module_extern_case) { SKIP_UNSUPPORTED_PLATFORM; std::unique_ptr<Module> A, B; Function *FA, *FB; createTwoModuleExternCase(A, FA, B, FB); createJIT(std::move(A)); TheJIT->addModule(std::move(B)); uint64_t ptr = TheJIT->getFunctionAddress(FA->getName().str()); checkAdd(ptr); ptr = TheJIT->getFunctionAddress(FB->getName().str()); checkAdd(ptr); } // Module A { Function FA1, Function FA2 which calls FA1 }, // Module B { Extern FA1, Function FB which calls FA1 }, // execute FB then FA2 TEST_F(MCJITMultipleModuleTest, two_module_consecutive_call_case) { SKIP_UNSUPPORTED_PLATFORM; std::unique_ptr<Module> A, B; Function *FA1, *FA2, *FB; createTwoModuleExternCase(A, FA1, B, FB); FA2 = insertSimpleCallFunction<int32_t(int32_t, int32_t)>(A.get(), FA1); createJIT(std::move(A)); TheJIT->addModule(std::move(B)); uint64_t ptr = TheJIT->getFunctionAddress(FB->getName().str()); TheJIT->finalizeObject(); checkAdd(ptr); ptr = TheJIT->getFunctionAddress(FA2->getName().str()); checkAdd(ptr); } // TODO: // Module A { Extern Global GVB, Global Variable GVA, Function FA loads GVB }, // Module B { Extern Global GVA, Global Variable GVB, Function FB loads GVA }, // Module A { Global Variable GVA, Function FA loads GVA }, // Module B { Global Variable GVB, Internal Global GVC, Function FB loads GVB }, // execute FB then FA, also check that the global variables are properly accesible // through the ExecutionEngine APIs TEST_F(MCJITMultipleModuleTest, two_module_global_variables_case) { SKIP_UNSUPPORTED_PLATFORM; std::unique_ptr<Module> A, B; Function *FA, *FB; GlobalVariable *GVA, *GVB, *GVC; A.reset(createEmptyModule("A")); B.reset(createEmptyModule("B")); int32_t initialNum = 7; GVA = insertGlobalInt32(A.get(), "GVA", initialNum); GVB = insertGlobalInt32(B.get(), "GVB", initialNum); FA = startFunction<int32_t(void)>(A.get(), "FA"); endFunctionWithRet(FA, Builder.CreateLoad(GVA)); FB = startFunction<int32_t(void)>(B.get(), "FB"); endFunctionWithRet(FB, Builder.CreateLoad(GVB)); GVC = insertGlobalInt32(B.get(), "GVC", initialNum); GVC->setLinkage(GlobalValue::InternalLinkage); createJIT(std::move(A)); TheJIT->addModule(std::move(B)); EXPECT_EQ(GVA, TheJIT->FindGlobalVariableNamed("GVA")); EXPECT_EQ(GVB, TheJIT->FindGlobalVariableNamed("GVB")); EXPECT_EQ(GVC, TheJIT->FindGlobalVariableNamed("GVC",true)); EXPECT_EQ(nullptr, TheJIT->FindGlobalVariableNamed("GVC")); uint64_t FBPtr = TheJIT->getFunctionAddress(FB->getName().str()); TheJIT->finalizeObject(); EXPECT_TRUE(0 != FBPtr); int32_t(*FuncPtr)() = (int32_t(*)())FBPtr; EXPECT_EQ(initialNum, FuncPtr()) << "Invalid value for global returned from JITted function in module B"; uint64_t FAPtr = TheJIT->getFunctionAddress(FA->getName().str()); EXPECT_TRUE(0 != FAPtr); FuncPtr = (int32_t(*)())FAPtr; EXPECT_EQ(initialNum, FuncPtr()) << "Invalid value for global returned from JITted function in module A"; } // Module A { Function FA }, // Module B { Extern FA, Function FB which calls FA }, // Module C { Extern FA, Function FC which calls FA }, // execute FC, FB, FA TEST_F(MCJITMultipleModuleTest, three_module_case) { SKIP_UNSUPPORTED_PLATFORM; std::unique_ptr<Module> A, B, C; Function *FA, *FB, *FC; createThreeModuleCase(A, FA, B, FB, C, FC); createJIT(std::move(A)); TheJIT->addModule(std::move(B)); TheJIT->addModule(std::move(C)); uint64_t ptr = TheJIT->getFunctionAddress(FC->getName().str()); checkAdd(ptr); ptr = TheJIT->getFunctionAddress(FB->getName().str()); checkAdd(ptr); ptr = TheJIT->getFunctionAddress(FA->getName().str()); checkAdd(ptr); } // Module A { Function FA }, // Module B { Extern FA, Function FB which calls FA }, // Module C { Extern FA, Function FC which calls FA }, // execute FA, FB, FC TEST_F(MCJITMultipleModuleTest, three_module_case_reverse_order) { SKIP_UNSUPPORTED_PLATFORM; std::unique_ptr<Module> A, B, C; Function *FA, *FB, *FC; createThreeModuleCase(A, FA, B, FB, C, FC); createJIT(std::move(A)); TheJIT->addModule(std::move(B)); TheJIT->addModule(std::move(C)); uint64_t ptr = TheJIT->getFunctionAddress(FA->getName().str()); checkAdd(ptr); ptr = TheJIT->getFunctionAddress(FB->getName().str()); checkAdd(ptr); ptr = TheJIT->getFunctionAddress(FC->getName().str()); checkAdd(ptr); } // Module A { Function FA }, // Module B { Extern FA, Function FB which calls FA }, // Module C { Extern FB, Function FC which calls FB }, // execute FC, FB, FA TEST_F(MCJITMultipleModuleTest, three_module_chain_case) { SKIP_UNSUPPORTED_PLATFORM; std::unique_ptr<Module> A, B, C; Function *FA, *FB, *FC; createThreeModuleChainedCallsCase(A, FA, B, FB, C, FC); createJIT(std::move(A)); TheJIT->addModule(std::move(B)); TheJIT->addModule(std::move(C)); uint64_t ptr = TheJIT->getFunctionAddress(FC->getName().str()); checkAdd(ptr); ptr = TheJIT->getFunctionAddress(FB->getName().str()); checkAdd(ptr); ptr = TheJIT->getFunctionAddress(FA->getName().str()); checkAdd(ptr); } // Module A { Function FA }, // Module B { Extern FA, Function FB which calls FA }, // Module C { Extern FB, Function FC which calls FB }, // execute FA, FB, FC TEST_F(MCJITMultipleModuleTest, three_modules_chain_case_reverse_order) { SKIP_UNSUPPORTED_PLATFORM; std::unique_ptr<Module> A, B, C; Function *FA, *FB, *FC; createThreeModuleChainedCallsCase(A, FA, B, FB, C, FC); createJIT(std::move(A)); TheJIT->addModule(std::move(B)); TheJIT->addModule(std::move(C)); uint64_t ptr = TheJIT->getFunctionAddress(FA->getName().str()); checkAdd(ptr); ptr = TheJIT->getFunctionAddress(FB->getName().str()); checkAdd(ptr); ptr = TheJIT->getFunctionAddress(FC->getName().str()); checkAdd(ptr); } // Module A { Extern FB, Function FA which calls FB1 }, // Module B { Extern FA, Function FB1, Function FB2 which calls FA }, // execute FA, then FB1 // FIXME: this test case is not supported by MCJIT TEST_F(MCJITMultipleModuleTest, cross_module_dependency_case) { SKIP_UNSUPPORTED_PLATFORM; std::unique_ptr<Module> A, B; Function *FA, *FB1, *FB2; createCrossModuleRecursiveCase(A, FA, B, FB1, FB2); createJIT(std::move(A)); TheJIT->addModule(std::move(B)); uint64_t ptr = TheJIT->getFunctionAddress(FA->getName().str()); checkAccumulate(ptr); ptr = TheJIT->getFunctionAddress(FB1->getName().str()); checkAccumulate(ptr); } // Module A { Extern FB, Function FA which calls FB1 }, // Module B { Extern FA, Function FB1, Function FB2 which calls FA }, // execute FB1 then FA // FIXME: this test case is not supported by MCJIT TEST_F(MCJITMultipleModuleTest, cross_module_dependency_case_reverse_order) { SKIP_UNSUPPORTED_PLATFORM; std::unique_ptr<Module> A, B; Function *FA, *FB1, *FB2; createCrossModuleRecursiveCase(A, FA, B, FB1, FB2); createJIT(std::move(A)); TheJIT->addModule(std::move(B)); uint64_t ptr = TheJIT->getFunctionAddress(FB1->getName().str()); checkAccumulate(ptr); ptr = TheJIT->getFunctionAddress(FA->getName().str()); checkAccumulate(ptr); } // Module A { Extern FB1, Function FA which calls FB1 }, // Module B { Extern FA, Function FB1, Function FB2 which calls FA }, // execute FB1 then FB2 // FIXME: this test case is not supported by MCJIT TEST_F(MCJITMultipleModuleTest, cross_module_dependency_case3) { SKIP_UNSUPPORTED_PLATFORM; std::unique_ptr<Module> A, B; Function *FA, *FB1, *FB2; createCrossModuleRecursiveCase(A, FA, B, FB1, FB2); createJIT(std::move(A)); TheJIT->addModule(std::move(B)); uint64_t ptr = TheJIT->getFunctionAddress(FB1->getName().str()); checkAccumulate(ptr); ptr = TheJIT->getFunctionAddress(FB2->getName().str()); checkAccumulate(ptr); } // Test that FindFunctionNamed finds the definition of // a function in the correct module. We check two functions // in two different modules, to make sure that for at least // one of them MCJIT had to ignore the extern declaration. TEST_F(MCJITMultipleModuleTest, FindFunctionNamed_test) { SKIP_UNSUPPORTED_PLATFORM; std::unique_ptr<Module> A, B; Function *FA, *FB1, *FB2; createCrossModuleRecursiveCase(A, FA, B, FB1, FB2); createJIT(std::move(A)); TheJIT->addModule(std::move(B)); EXPECT_EQ(FA, TheJIT->FindFunctionNamed(FA->getName().data())); EXPECT_EQ(FB1, TheJIT->FindFunctionNamed(FB1->getName().data())); } } // end anonymous namespace