//===-- ArchitectureArm.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 "Plugins/Architecture/Arm/ArchitectureArm.h" #include "Plugins/Process/Utility/ARMDefines.h" #include "Plugins/Process/Utility/InstructionUtils.h" #include "lldb/Core/PluginManager.h" #include "lldb/Target/RegisterContext.h" #include "lldb/Target/Thread.h" #include "lldb/Utility/ArchSpec.h" using namespace lldb_private; using namespace lldb; LLDB_PLUGIN_DEFINE(ArchitectureArm) ConstString ArchitectureArm::GetPluginNameStatic() { return ConstString("arm"); } void ArchitectureArm::Initialize() { PluginManager::RegisterPlugin(GetPluginNameStatic(), "Arm-specific algorithms", &ArchitectureArm::Create); } void ArchitectureArm::Terminate() { PluginManager::UnregisterPlugin(&ArchitectureArm::Create); } std::unique_ptr ArchitectureArm::Create(const ArchSpec &arch) { if (arch.GetMachine() != llvm::Triple::arm) return nullptr; return std::unique_ptr(new ArchitectureArm()); } ConstString ArchitectureArm::GetPluginName() { return GetPluginNameStatic(); } uint32_t ArchitectureArm::GetPluginVersion() { return 1; } void ArchitectureArm::OverrideStopInfo(Thread &thread) const { // We need to check if we are stopped in Thumb mode in a IT instruction and // detect if the condition doesn't pass. If this is the case it means we // won't actually execute this instruction. If this happens we need to clear // the stop reason to no thread plans think we are stopped for a reason and // the plans should keep going. // // We do this because when single stepping many ARM processes, debuggers // often use the BVR/BCR registers that says "stop when the PC is not equal // to its current value". This method of stepping means we can end up // stopping on instructions inside an if/then block that wouldn't get // executed. By fixing this we can stop the debugger from seeming like you // stepped through both the "if" _and_ the "else" clause when source level // stepping because the debugger stops regardless due to the BVR/BCR // triggering a stop. // // It also means we can set breakpoints on instructions inside an an if/then // block and correctly skip them if we use the BKPT instruction. The ARM and // Thumb BKPT instructions are unconditional even when executed in a Thumb IT // block. // // If your debugger inserts software traps in ARM/Thumb code, it will need to // use 16 and 32 bit instruction for 16 and 32 bit thumb instructions // respectively. If your debugger inserts a 16 bit thumb trap on top of a 32 // bit thumb instruction for an opcode that is inside an if/then, it will // change the it/then to conditionally execute your // 16 bit trap and then cause your program to crash if it executes the // trailing 16 bits (the second half of the 32 bit thumb instruction you // partially overwrote). RegisterContextSP reg_ctx_sp(thread.GetRegisterContext()); if (!reg_ctx_sp) return; const uint32_t cpsr = reg_ctx_sp->GetFlags(0); if (cpsr == 0) return; // Read the J and T bits to get the ISETSTATE const uint32_t J = Bit32(cpsr, 24); const uint32_t T = Bit32(cpsr, 5); const uint32_t ISETSTATE = J << 1 | T; if (ISETSTATE == 0) { // NOTE: I am pretty sure we want to enable the code below // that detects when we stop on an instruction in ARM mode that is conditional // and the condition doesn't pass. This can happen if you set a breakpoint on // an instruction that is conditional. We currently will _always_ stop on the // instruction which is bad. You can also run into this while single stepping // and you could appear to run code in the "if" and in the "else" clause // because it would stop at all of the conditional instructions in both. In // such cases, we really don't want to stop at this location. // I will check with the lldb-dev list first before I enable this. #if 0 // ARM mode: check for condition on instruction const addr_t pc = reg_ctx_sp->GetPC(); Status error; // If we fail to read the opcode we will get UINT64_MAX as the result in // "opcode" which we can use to detect if we read a valid opcode. const uint64_t opcode = thread.GetProcess()->ReadUnsignedIntegerFromMemory(pc, 4, UINT64_MAX, error); if (opcode <= UINT32_MAX) { const uint32_t condition = Bits32((uint32_t)opcode, 31, 28); if (!ARMConditionPassed(condition, cpsr)) { // We ARE stopped on an ARM instruction whose condition doesn't // pass so this instruction won't get executed. Regardless of why // it stopped, we need to clear the stop info thread.SetStopInfo (StopInfoSP()); } } #endif } else if (ISETSTATE == 1) { // Thumb mode const uint32_t ITSTATE = Bits32(cpsr, 15, 10) << 2 | Bits32(cpsr, 26, 25); if (ITSTATE != 0) { const uint32_t condition = Bits32(ITSTATE, 7, 4); if (!ARMConditionPassed(condition, cpsr)) { // We ARE stopped in a Thumb IT instruction on an instruction whose // condition doesn't pass so this instruction won't get executed. // Regardless of why it stopped, we need to clear the stop info thread.SetStopInfo(StopInfoSP()); } } } } addr_t ArchitectureArm::GetCallableLoadAddress(addr_t code_addr, AddressClass addr_class) const { bool is_alternate_isa = false; switch (addr_class) { case AddressClass::eData: case AddressClass::eDebug: return LLDB_INVALID_ADDRESS; case AddressClass::eCodeAlternateISA: is_alternate_isa = true; break; default: break; } if ((code_addr & 2u) || is_alternate_isa) return code_addr | 1u; return code_addr; } addr_t ArchitectureArm::GetOpcodeLoadAddress(addr_t opcode_addr, AddressClass addr_class) const { switch (addr_class) { case AddressClass::eData: case AddressClass::eDebug: return LLDB_INVALID_ADDRESS; default: break; } return opcode_addr & ~(1ull); }