2018-09-22 02:56:44 +08:00
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//===-- ArchitectureMips.cpp -------------------------------------*- C++ -*-===//
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//
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// The LLVM Compiler Infrastructure
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//
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// This file is distributed under the University of Illinois Open Source
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// License. See LICENSE.TXT for details.
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//
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//===----------------------------------------------------------------------===//
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#include "Plugins/Architecture/Mips/ArchitectureMips.h"
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#include "lldb/Core/Address.h"
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#include "lldb/Core/Disassembler.h"
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#include "lldb/Core/Module.h"
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#include "lldb/Core/PluginManager.h"
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#include "lldb/Symbol/Function.h"
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#include "lldb/Symbol/SymbolContext.h"
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#include "lldb/Target/SectionLoadList.h"
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#include "lldb/Target/Target.h"
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#include "lldb/Utility/ArchSpec.h"
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#include "lldb/Utility/Log.h"
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using namespace lldb_private;
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using namespace lldb;
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ConstString ArchitectureMips::GetPluginNameStatic() {
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return ConstString("mips");
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}
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void ArchitectureMips::Initialize() {
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PluginManager::RegisterPlugin(GetPluginNameStatic(),
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"Mips-specific algorithms",
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&ArchitectureMips::Create);
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}
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void ArchitectureMips::Terminate() {
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PluginManager::UnregisterPlugin(&ArchitectureMips::Create);
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}
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std::unique_ptr<Architecture> ArchitectureMips::Create(const ArchSpec &arch) {
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return arch.IsMIPS() ?
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std::unique_ptr<Architecture>(new ArchitectureMips(arch)) : nullptr;
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}
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ConstString ArchitectureMips::GetPluginName() { return GetPluginNameStatic(); }
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uint32_t ArchitectureMips::GetPluginVersion() { return 1; }
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addr_t ArchitectureMips::GetCallableLoadAddress(addr_t code_addr,
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AddressClass addr_class) const {
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bool is_alternate_isa = false;
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switch (addr_class) {
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case AddressClass::eData:
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case AddressClass::eDebug:
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return LLDB_INVALID_ADDRESS;
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case AddressClass::eCodeAlternateISA:
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is_alternate_isa = true;
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break;
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default: break;
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}
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if ((code_addr & 2ull) || is_alternate_isa)
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return code_addr | 1u;
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return code_addr;
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}
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addr_t ArchitectureMips::GetOpcodeLoadAddress(addr_t opcode_addr,
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AddressClass addr_class) const {
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switch (addr_class) {
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case AddressClass::eData:
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case AddressClass::eDebug:
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return LLDB_INVALID_ADDRESS;
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default: break;
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}
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return opcode_addr & ~(1ull);
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}
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lldb::addr_t ArchitectureMips::GetBreakableLoadAddress(lldb::addr_t addr,
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Target &target) const {
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Log *log(lldb_private::GetLogIfAllCategoriesSet(LIBLLDB_LOG_BREAKPOINTS));
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Address resolved_addr;
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SectionLoadList §ion_load_list = target.GetSectionLoadList();
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if (section_load_list.IsEmpty())
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// No sections are loaded, so we must assume we are not running yet and
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// need to operate only on file address.
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target.ResolveFileAddress(addr, resolved_addr);
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else
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target.ResolveLoadAddress(addr, resolved_addr);
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addr_t current_offset = 0;
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// Get the function boundaries to make sure we don't scan back before the
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// beginning of the current function.
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ModuleSP temp_addr_module_sp(resolved_addr.GetModule());
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if (temp_addr_module_sp) {
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SymbolContext sc;
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2018-10-26 04:45:19 +08:00
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SymbolContextItem resolve_scope =
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eSymbolContextFunction | eSymbolContextSymbol;
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2018-09-22 02:56:44 +08:00
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temp_addr_module_sp->ResolveSymbolContextForAddress(resolved_addr,
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resolve_scope, sc);
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Address sym_addr;
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if (sc.function)
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sym_addr = sc.function->GetAddressRange().GetBaseAddress();
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else if (sc.symbol)
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sym_addr = sc.symbol->GetAddress();
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addr_t function_start = sym_addr.GetLoadAddress(&target);
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if (function_start == LLDB_INVALID_ADDRESS)
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function_start = sym_addr.GetFileAddress();
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if (function_start)
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current_offset = addr - function_start;
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}
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// If breakpoint address is start of function then we dont have to do
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// anything.
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if (current_offset == 0)
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return addr;
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ExecutionContext ctx;
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target.CalculateExecutionContext(ctx);
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auto insn = GetInstructionAtAddress(ctx, current_offset, addr);
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if (nullptr == insn || !insn->HasDelaySlot())
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return addr;
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// Adjust the breakable address
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auto breakable_addr = addr - insn->GetOpcode().GetByteSize();
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if (log)
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log->Printf("Target::%s Breakpoint at 0x%8.8" PRIx64
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" is adjusted to 0x%8.8" PRIx64 " due to delay slot\n",
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__FUNCTION__, addr, breakable_addr);
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return breakable_addr;
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}
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Instruction *ArchitectureMips::GetInstructionAtAddress(
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const ExecutionContext &exe_ctx, const Address &resolved_addr,
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addr_t symbol_offset) const {
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auto loop_count = symbol_offset / 2;
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uint32_t arch_flags = m_arch.GetFlags();
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bool IsMips16 = arch_flags & ArchSpec::eMIPSAse_mips16;
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bool IsMicromips = arch_flags & ArchSpec::eMIPSAse_micromips;
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if (loop_count > 3) {
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// Scan previous 6 bytes
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if (IsMips16 | IsMicromips)
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loop_count = 3;
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// For mips-only, instructions are always 4 bytes, so scan previous 4
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// bytes only.
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else
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loop_count = 2;
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}
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// Create Disassembler Instance
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lldb::DisassemblerSP disasm_sp(
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Disassembler::FindPlugin(m_arch, nullptr, nullptr));
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InstructionList instruction_list;
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InstructionSP prev_insn;
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bool prefer_file_cache = true; // Read from file
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uint32_t inst_to_choose = 0;
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Address addr = resolved_addr;
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for (uint32_t i = 1; i <= loop_count; i++) {
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// Adjust the address to read from.
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addr.Slide(-2);
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AddressRange range(addr, i * 2);
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uint32_t insn_size = 0;
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disasm_sp->ParseInstructions(&exe_ctx, range, nullptr, prefer_file_cache);
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uint32_t num_insns = disasm_sp->GetInstructionList().GetSize();
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if (num_insns) {
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prev_insn = disasm_sp->GetInstructionList().GetInstructionAtIndex(0);
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insn_size = prev_insn->GetOpcode().GetByteSize();
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if (i == 1 && insn_size == 2) {
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// This looks like a valid 2-byte instruction (but it could be a part
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// of upper 4 byte instruction).
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instruction_list.Append(prev_insn);
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inst_to_choose = 1;
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}
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else if (i == 2) {
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// Here we may get one 4-byte instruction or two 2-byte instructions.
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if (num_insns == 2) {
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// Looks like there are two 2-byte instructions above our
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// breakpoint target address. Now the upper 2-byte instruction is
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// either a valid 2-byte instruction or could be a part of it's
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// upper 4-byte instruction. In both cases we don't care because in
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// this case lower 2-byte instruction is definitely a valid
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// instruction and whatever i=1 iteration has found out is true.
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inst_to_choose = 1;
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break;
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}
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else if (insn_size == 4) {
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// This instruction claims its a valid 4-byte instruction. But it
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// could be a part of it's upper 4-byte instruction. Lets try
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// scanning upper 2 bytes to verify this.
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instruction_list.Append(prev_insn);
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inst_to_choose = 2;
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}
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}
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else if (i == 3) {
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if (insn_size == 4)
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// FIXME: We reached here that means instruction at [target - 4] has
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// already claimed to be a 4-byte instruction, and now instruction
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// at [target - 6] is also claiming that it's a 4-byte instruction.
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// This can not be true. In this case we can not decide the valid
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// previous instruction so we let lldb set the breakpoint at the
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// address given by user.
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inst_to_choose = 0;
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else
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// This is straight-forward
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inst_to_choose = 2;
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break;
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}
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}
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else {
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// Decode failed, bytes do not form a valid instruction. So whatever
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// previous iteration has found out is true.
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if (i > 1) {
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inst_to_choose = i - 1;
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break;
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}
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}
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}
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// Check if we are able to find any valid instruction.
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if (inst_to_choose) {
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if (inst_to_choose > instruction_list.GetSize())
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inst_to_choose--;
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return instruction_list.GetInstructionAtIndex(inst_to_choose - 1).get();
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}
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return nullptr;
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}
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