/* * Copyright 2019 Google, Inc. * * 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 the copyright holders 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. * * Authors: Gabe Black */ #include #include #include #include "sim/guest_abi.hh" // Fake ThreadContext which holds data and captures results. class ThreadContext { public: static const int ints[]; static const double floats[]; static const int DefaultIntResult; static const double DefaultFloatResult; int intResult = DefaultIntResult; double floatResult = DefaultFloatResult; }; const int ThreadContext::ints[] = { 0, 1, 2, 3, 4, 5, 6, 7 }; const double ThreadContext::floats[] = { 10.0, 11.0, 12.0, 13.0, 14.0, 15.0, 16.0, 17.0 }; const int ThreadContext::DefaultIntResult = 0; const double ThreadContext::DefaultFloatResult = 0.0; // ABI anchor for an ABI which has 1D progress. Conceptually, this could be // because integer and floating point arguments are stored in the same // registers. struct TestABI_1D { using Position = int; }; // ABI anchor for an ABI which allocates a register for non-void return types. struct TestABI_RetReg { using Position = int; }; // ABI anchor for an ABI which has 2D progress. Conceptually, this could be // because integer and floating point arguments are stored in separate // registers. struct TestABI_2D { using Position = std::pair; }; namespace GuestABI { // Hooks for the 1D ABI arguments and return value. Add 1 or 1.0 to return // values so we can tell they went through the right set of hooks. template <> struct Argument { static int get(ThreadContext *tc, TestABI_1D::Position &position) { return tc->ints[position++]; } }; template struct Argument::value>::type> { static Arg get(ThreadContext *tc, TestABI_1D::Position &position) { return tc->floats[position++]; } }; template <> struct Result { static void store(ThreadContext *tc, const int &ret) { tc->intResult = ret + 1; } }; template struct Result::value>::type> { static void store(ThreadContext *tc, const Ret &ret) { tc->floatResult = ret + 1.0; } }; // Hooks for the return value allocating ABI. It uses the same rules as the // 1D ABI for arguments, but allocates space for and discards return values. template struct Argument : public Argument {}; template struct Result { static void store(ThreadContext *tc, const Ret &ret) {} static void allocate(ThreadContext *tc, TestABI_RetReg::Position &position) { position++; } }; // Hooks for the 2D ABI arguments and return value. Add 2 or 2.0 to return // values so we can tell they went through the right set of hooks. template <> struct Argument { static int get(ThreadContext *tc, TestABI_2D::Position &position) { return tc->ints[position.first++]; } }; template struct Argument::value>::type> { static Arg get(ThreadContext *tc, TestABI_2D::Position &position) { return tc->floats[position.second++]; } }; template <> struct Result { static void store(ThreadContext *tc, const int &ret) { tc->intResult = ret + 2; } }; template struct Result::value>::type> { static void store(ThreadContext *tc, const Ret &ret) { tc->floatResult = ret + 2.0; } }; } // namespace GuestABI // Test function which verifies that its arguments reflect the 1D ABI and // which doesn't return anything. void testIntVoid(ThreadContext *tc, int a, float b, int c, double d, GuestABI::VarArgs varargs) { EXPECT_EQ(a, tc->ints[0]); EXPECT_EQ(b, tc->floats[1]); EXPECT_EQ(c, tc->ints[2]); EXPECT_EQ(d, tc->floats[3]); EXPECT_EQ(varargs.get(), tc->ints[4]); EXPECT_EQ(varargs.get(), tc->floats[5]); EXPECT_EQ(varargs.get(), tc->floats[6]); } // Test functions which verify that the return allocating ABI allocates space // for its return value successfully. void testRetRegVoid(ThreadContext *tc, int a) { EXPECT_EQ(a, tc->ints[0]); } int testRetRegInt(ThreadContext *tc, int a) { EXPECT_EQ(a, tc->ints[1]); return 0; } // Test function which verifies that its arguments reflect the 2D ABI and // which doesn't return anything. void test2DVoid(ThreadContext *tc, int a, float b, int c, double d, GuestABI::VarArgs varargs) { EXPECT_EQ(a, tc->ints[0]); EXPECT_EQ(b, tc->floats[0]); EXPECT_EQ(c, tc->ints[1]); EXPECT_EQ(d, tc->floats[1]); EXPECT_EQ(varargs.get(), tc->ints[2]); EXPECT_EQ(varargs.get(), tc->floats[2]); EXPECT_EQ(varargs.get(), tc->floats[3]); } // Test functions which returns various types of values. const int IntRetValue = 50; const float FloatRetValue = 3.14; const double DoubleRetValue = 12.34; int testIntRet(ThreadContext *tc) { return IntRetValue; } float testFloatRet(ThreadContext *tc) { return FloatRetValue; } double testDoubleRet(ThreadContext *tc) { return DoubleRetValue; } // The actual test bodies. TEST(GuestABI, ABI_1D_args) { ThreadContext tc; invokeSimcall(&tc, testIntVoid); EXPECT_EQ(tc.intResult, tc.DefaultIntResult); EXPECT_EQ(tc.floatResult, tc.DefaultFloatResult); } TEST(GuestABI, ABI_RetReg) { ThreadContext tc; invokeSimcall(&tc, testRetRegVoid); invokeSimcall(&tc, testRetRegInt); } TEST(GuestABI, ABI_2D_args) { ThreadContext tc; invokeSimcall(&tc, test2DVoid); EXPECT_EQ(tc.intResult, tc.DefaultIntResult); EXPECT_EQ(tc.floatResult, tc.DefaultFloatResult); } TEST(GuestABI, ABI_returns) { // 1D returns. { ThreadContext tc; int ret = invokeSimcall(&tc, testIntRet); EXPECT_EQ(ret, IntRetValue); EXPECT_EQ(tc.intResult, IntRetValue + 1); EXPECT_EQ(tc.floatResult, tc.DefaultFloatResult); } { ThreadContext tc; float ret = invokeSimcall(&tc, testFloatRet); EXPECT_EQ(ret, FloatRetValue); EXPECT_EQ(tc.intResult, tc.DefaultIntResult); EXPECT_EQ(tc.floatResult, FloatRetValue + 1.0); } { ThreadContext tc; double ret = invokeSimcall(&tc, testDoubleRet); EXPECT_EQ(ret, DoubleRetValue); EXPECT_EQ(tc.intResult, tc.DefaultIntResult); EXPECT_EQ(tc.floatResult, DoubleRetValue + 1.0); } // 2D returns. { ThreadContext tc; int ret = invokeSimcall(&tc, testIntRet); EXPECT_EQ(ret, IntRetValue); EXPECT_EQ(tc.intResult, IntRetValue + 2); EXPECT_EQ(tc.floatResult, tc.DefaultFloatResult); } { ThreadContext tc; float ret = invokeSimcall(&tc, testFloatRet); EXPECT_EQ(ret, FloatRetValue); EXPECT_EQ(tc.intResult, tc.DefaultIntResult); EXPECT_EQ(tc.floatResult, FloatRetValue + 2.0); } { ThreadContext tc; double ret = invokeSimcall(&tc, testDoubleRet); EXPECT_EQ(ret, DoubleRetValue); EXPECT_EQ(tc.intResult, tc.DefaultIntResult); EXPECT_EQ(tc.floatResult, DoubleRetValue + 2.0); } } TEST(GuestABI, dumpSimcall) { ThreadContext tc; std::string dump = dumpSimcall("test", &tc, testIntVoid); EXPECT_EQ(dump, "test(0, 11, 2, 13, ...)"); }