//===-- TestLoongArchEmulator.cpp -----------------------------------------===// // // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions. // See https://llvm.org/LICENSE.txt for license information. // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception // //===----------------------------------------------------------------------===// #include "lldb/Core/Address.h" #include "lldb/Core/Disassembler.h" #include "lldb/Core/PluginManager.h" #include "lldb/Target/ExecutionContext.h" #include "lldb/Utility/ArchSpec.h" #include "lldb/Utility/RegisterValue.h" #include "gtest/gtest.h" #include "Plugins/Instruction/LoongArch/EmulateInstructionLoongArch.h" #include "Plugins/Process/Utility/RegisterInfoPOSIX_loongarch64.h" #include "Plugins/Process/Utility/lldb-loongarch-register-enums.h" using namespace llvm; using namespace lldb; using namespace lldb_private; #define GEN_BCOND_TEST(bit, name, rj_val, rd_val_branched, rd_val_continued) \ TEST_F(LoongArch##bit##EmulatorTester, test##name##branched) { \ testBcondBranch(this, name, true, rj_val, rd_val_branched); \ } \ TEST_F(LoongArch##bit##EmulatorTester, test##name##continued) { \ testBcondBranch(this, name, false, rj_val, rd_val_continued); \ } #define GEN_BZCOND_TEST(bit, name, rj_val_branched, rj_val_continued) \ TEST_F(LoongArch##bit##EmulatorTester, test##name##branched) { \ testBZcondBranch(this, name, true, rj_val_branched); \ } \ TEST_F(LoongArch##bit##EmulatorTester, test##name##continued) { \ testBZcondBranch(this, name, false, rj_val_continued); \ } #define GEN_BCZCOND_TEST(bit, name, cj_val_branched, cj_val_continued) \ TEST_F(LoongArch##bit##EmulatorTester, test##name##branched) { \ testBCZcondBranch(this, name, true, cj_val_branched); \ } \ TEST_F(LoongArch##bit##EmulatorTester, test##name##continued) { \ testBCZcondBranch(this, name, false, cj_val_continued); \ } struct LoongArch64EmulatorTester : public EmulateInstructionLoongArch, testing::Test { RegisterInfoPOSIX_loongarch64::GPR gpr; RegisterInfoPOSIX_loongarch64::FPR fpr; LoongArch64EmulatorTester( std::string triple = "loongarch64-unknown-linux-gnu") : EmulateInstructionLoongArch(ArchSpec(triple)) { EmulateInstruction::SetReadRegCallback(ReadRegisterCallback); EmulateInstruction::SetWriteRegCallback(WriteRegisterCallback); } static bool ReadRegisterCallback(EmulateInstruction *instruction, void *baton, const RegisterInfo *reg_info, RegisterValue ®_value) { LoongArch64EmulatorTester *tester = (LoongArch64EmulatorTester *)instruction; uint32_t reg = reg_info->kinds[eRegisterKindLLDB]; if (reg >= gpr_r0_loongarch && reg <= gpr_r31_loongarch) reg_value.SetUInt(tester->gpr.gpr[reg], reg_info->byte_size); else if (reg == gpr_orig_a0_loongarch) reg_value.SetUInt(tester->gpr.orig_a0, reg_info->byte_size); else if (reg == gpr_pc_loongarch) reg_value.SetUInt(tester->gpr.csr_era, reg_info->byte_size); else if (reg == gpr_badv_loongarch) reg_value.SetUInt(tester->gpr.csr_badv, reg_info->byte_size); else if (reg == fpr_first_loongarch + 32) // fcc0 reg_value.SetUInt(tester->fpr.fcc, reg_info->byte_size); return true; } static bool WriteRegisterCallback(EmulateInstruction *instruction, void *baton, const Context &context, const RegisterInfo *reg_info, const RegisterValue ®_value) { LoongArch64EmulatorTester *tester = (LoongArch64EmulatorTester *)instruction; uint32_t reg = reg_info->kinds[eRegisterKindLLDB]; if (reg >= gpr_r0_loongarch && reg <= gpr_r31_loongarch) tester->gpr.gpr[reg] = reg_value.GetAsUInt64(); else if (reg == gpr_orig_a0_loongarch) tester->gpr.orig_a0 = reg_value.GetAsUInt64(); else if (reg == gpr_pc_loongarch) tester->gpr.csr_era = reg_value.GetAsUInt64(); else if (reg == gpr_badv_loongarch) tester->gpr.csr_badv = reg_value.GetAsUInt64(); return true; } }; // BEQ BNE BLT BGE BLTU BGEU static uint32_t EncodeBcondType(uint32_t opcode, uint32_t rj, uint32_t rd, uint32_t offs16) { offs16 = offs16 & 0x0000ffff; return opcode << 26 | offs16 << 10 | rj << 5 | rd; } static uint32_t BEQ(uint32_t rj, uint32_t rd, int32_t offs16) { return EncodeBcondType(0b010110, rj, rd, uint32_t(offs16)); } static uint32_t BNE(uint32_t rj, uint32_t rd, int32_t offs16) { return EncodeBcondType(0b010111, rj, rd, uint32_t(offs16)); } static uint32_t BLT(uint32_t rj, uint32_t rd, int32_t offs16) { return EncodeBcondType(0b011000, rj, rd, uint32_t(offs16)); } static uint32_t BGE(uint32_t rj, uint32_t rd, int32_t offs16) { return EncodeBcondType(0b011001, rj, rd, uint32_t(offs16)); } static uint32_t BLTU(uint32_t rj, uint32_t rd, int32_t offs16) { return EncodeBcondType(0b011010, rj, rd, uint32_t(offs16)); } static uint32_t BGEU(uint32_t rj, uint32_t rd, int32_t offs16) { return EncodeBcondType(0b011011, rj, rd, uint32_t(offs16)); } // BEQZ BNEZ static uint32_t EncodeBZcondType(uint32_t opcode, uint32_t rj, uint32_t offs21) { uint32_t offs20_16 = (offs21 & 0x001f0000) >> 16; uint32_t offs15_0 = offs21 & 0x0000ffff; return opcode << 26 | offs15_0 << 10 | rj << 5 | offs20_16; } static uint32_t BEQZ(uint32_t rj, int32_t offs21) { return EncodeBZcondType(0b010000, rj, uint32_t(offs21)); } static uint32_t BNEZ(uint32_t rj, int32_t offs21) { return EncodeBZcondType(0b010001, rj, uint32_t(offs21)); } // BCEQZ BCNEZ static uint32_t EncodeBCZcondType(uint32_t opcode, uint8_t cj, uint32_t offs21) { uint32_t offs20_16 = (offs21 & 0x001f0000) >> 16; uint32_t offs15_0 = offs21 & 0x0000ffff; return (opcode >> 2) << 26 | offs15_0 << 10 | (opcode & 0b11) << 8 | cj << 5 | offs20_16; } static uint32_t BCEQZ(uint8_t cj, int32_t offs21) { return EncodeBCZcondType(0b01001000, cj, uint32_t(offs21)); } static uint32_t BCNEZ(uint8_t cj, int32_t offs21) { return EncodeBCZcondType(0b01001001, cj, uint32_t(offs21)); } using EncoderBcond = uint32_t (*)(uint32_t rj, uint32_t rd, int32_t offs16); using EncoderBZcond = uint32_t (*)(uint32_t rj, int32_t offs21); using EncoderBCZcond = uint32_t (*)(uint8_t cj, int32_t offs21); TEST_F(LoongArch64EmulatorTester, testJIRL) { bool success = false; addr_t old_pc = 0x12000600; WritePC(old_pc); // JIRL r1, r12, 0x10 // | 31 26 | 25 10 | 9 5 | 4 0 | // | 0 1 0 0 1 1 | 0 0 0 0 0 0 0 0 0 0 0 1 0 0 0 0 | 0 1 1 0 0 | 0 0 0 0 1 | uint32_t inst = 0b01001100000000000100000110000001; uint32_t offs16 = 0x10; gpr.gpr[12] = 0x12000400; ASSERT_TRUE(TestExecute(inst)); auto r1 = gpr.gpr[1]; auto pc = ReadPC(&success); ASSERT_TRUE(success); ASSERT_EQ(r1, old_pc + 4); ASSERT_EQ(pc, gpr.gpr[12] + (offs16 * 4)); } TEST_F(LoongArch64EmulatorTester, testB) { bool success = false; addr_t old_pc = 0x12000600; WritePC(old_pc); // B 0x10010 // | 31 26 | 25 10 | 9 0 | // | 0 1 0 1 0 0 | 0 0 0 0 0 0 0 0 0 0 0 1 0 0 0 0 | 0 0 0 0 0 0 0 0 0 1 | uint32_t inst = 0b01010000000000000100000000000001; uint32_t offs26 = 0x10010; ASSERT_TRUE(TestExecute(inst)); auto pc = ReadPC(&success); ASSERT_TRUE(success); ASSERT_EQ(pc, old_pc + (offs26 * 4)); } TEST_F(LoongArch64EmulatorTester, testBL) { bool success = false; addr_t old_pc = 0x12000600; WritePC(old_pc); // BL 0x10010 // | 31 26 | 25 10 | 9 0 | // | 0 1 0 1 0 1 | 0 0 0 0 0 0 0 0 0 0 0 1 0 0 0 0 | 0 0 0 0 0 0 0 0 0 1 | uint32_t inst = 0b01010100000000000100000000000001; uint32_t offs26 = 0x10010; ASSERT_TRUE(TestExecute(inst)); auto r1 = gpr.gpr[1]; auto pc = ReadPC(&success); ASSERT_TRUE(success); ASSERT_EQ(r1, old_pc + 4); ASSERT_EQ(pc, old_pc + (offs26 * 4)); } static void testBcondBranch(LoongArch64EmulatorTester *tester, EncoderBcond encoder, bool branched, uint64_t rj_val, uint64_t rd_val) { bool success = false; addr_t old_pc = 0x12000600; tester->WritePC(old_pc); tester->gpr.gpr[12] = rj_val; tester->gpr.gpr[13] = rd_val; // b r12, r13, (-256) uint32_t inst = encoder(12, 13, -256); ASSERT_TRUE(tester->TestExecute(inst)); auto pc = tester->ReadPC(&success); ASSERT_TRUE(success); ASSERT_EQ(pc, old_pc + (branched ? (-256 * 4) : 4)); } static void testBZcondBranch(LoongArch64EmulatorTester *tester, EncoderBZcond encoder, bool branched, uint64_t rj_val) { bool success = false; addr_t old_pc = 0x12000600; tester->WritePC(old_pc); tester->gpr.gpr[4] = rj_val; // bz r4, (-256) uint32_t inst = encoder(4, -256); ASSERT_TRUE(tester->TestExecute(inst)); auto pc = tester->ReadPC(&success); ASSERT_TRUE(success); ASSERT_EQ(pc, old_pc + (branched ? (-256 * 4) : 4)); } static void testBCZcondBranch(LoongArch64EmulatorTester *tester, EncoderBCZcond encoder, bool branched, uint32_t cj_val) { bool success = false; addr_t old_pc = 0x12000600; tester->WritePC(old_pc); tester->fpr.fcc = cj_val; // bcz fcc0, 256 uint32_t inst = encoder(0, 256); ASSERT_TRUE(tester->TestExecute(inst)); auto pc = tester->ReadPC(&success); ASSERT_TRUE(success); ASSERT_EQ(pc, old_pc + (branched ? (256 * 4) : 4)); } GEN_BCOND_TEST(64, BEQ, 1, 1, 0) GEN_BCOND_TEST(64, BNE, 1, 0, 1) GEN_BCOND_TEST(64, BLT, -2, 1, -3) GEN_BCOND_TEST(64, BGE, -2, -3, 1) GEN_BCOND_TEST(64, BLTU, -2, -1, 1) GEN_BCOND_TEST(64, BGEU, -2, 1, -1) GEN_BZCOND_TEST(64, BEQZ, 0, 1) GEN_BZCOND_TEST(64, BNEZ, 1, 0) GEN_BCZCOND_TEST(64, BCEQZ, 0, 1) GEN_BCZCOND_TEST(64, BCNEZ, 1, 0)