/* * Copyright (C) 2016 The Android Open Source Project * * Licensed under the Apache License, Version 2.0 (the "License"); * you may not use this file except in compliance with the License. * You may obtain a copy of the License at * * http://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. */ #ifndef ART_COMPILER_DEBUG_ELF_DEBUG_LOC_WRITER_H_ #define ART_COMPILER_DEBUG_ELF_DEBUG_LOC_WRITER_H_ #include #include #include "arch/instruction_set.h" #include "compiled_method.h" #include "debug/method_debug_info.h" #include "dwarf/debug_info_entry_writer.h" #include "dwarf/register.h" #include "stack_map.h" namespace art { namespace debug { using Reg = dwarf::Reg; static Reg GetDwarfCoreReg(InstructionSet isa, int machine_reg) { switch (isa) { case InstructionSet::kArm: case InstructionSet::kThumb2: return Reg::ArmCore(machine_reg); case InstructionSet::kArm64: return Reg::Arm64Core(machine_reg); case InstructionSet::kX86: return Reg::X86Core(machine_reg); case InstructionSet::kX86_64: return Reg::X86_64Core(machine_reg); case InstructionSet::kMips: return Reg::MipsCore(machine_reg); case InstructionSet::kMips64: return Reg::Mips64Core(machine_reg); case InstructionSet::kNone: LOG(FATAL) << "No instruction set"; } UNREACHABLE(); } static Reg GetDwarfFpReg(InstructionSet isa, int machine_reg) { switch (isa) { case InstructionSet::kArm: case InstructionSet::kThumb2: return Reg::ArmFp(machine_reg); case InstructionSet::kArm64: return Reg::Arm64Fp(machine_reg); case InstructionSet::kX86: return Reg::X86Fp(machine_reg); case InstructionSet::kX86_64: return Reg::X86_64Fp(machine_reg); case InstructionSet::kMips: return Reg::MipsFp(machine_reg); case InstructionSet::kMips64: return Reg::Mips64Fp(machine_reg); case InstructionSet::kNone: LOG(FATAL) << "No instruction set"; } UNREACHABLE(); } struct VariableLocation { uint32_t low_pc; // Relative to compilation unit. uint32_t high_pc; // Relative to compilation unit. DexRegisterLocation reg_lo; // May be None if the location is unknown. DexRegisterLocation reg_hi; // Most significant bits of 64-bit value. }; // Get the location of given dex register (e.g. stack or machine register). // Note that the location might be different based on the current pc. // The result will cover all ranges where the variable is in scope. // PCs corresponding to stackmap with dex register map are accurate, // all other PCs are best-effort only. static std::vector GetVariableLocations( const MethodDebugInfo* method_info, const std::vector& dex_register_maps, uint16_t vreg, bool is64bitValue, uint64_t compilation_unit_code_address, uint32_t dex_pc_low, uint32_t dex_pc_high, InstructionSet isa) { std::vector variable_locations; // Get stack maps sorted by pc (they might not be sorted internally). // TODO(dsrbecky) Remove this once stackmaps get sorted by pc. const CodeInfo code_info(method_info->code_info); std::map stack_maps; // low_pc -> stack_map_index. for (uint32_t s = 0; s < code_info.GetNumberOfStackMaps(); s++) { StackMap stack_map = code_info.GetStackMapAt(s); DCHECK(stack_map.IsValid()); if (!stack_map.HasDexRegisterMap()) { // The compiler creates stackmaps without register maps at the start of // basic blocks in order to keep instruction-accurate line number mapping. // However, we never stop at those (breakpoint locations always have map). // Therefore, for the purpose of local variables, we ignore them. // The main reason for this is to save space by avoiding undefined gaps. continue; } const uint32_t pc_offset = stack_map.GetNativePcOffset(isa); DCHECK_LE(pc_offset, method_info->code_size); DCHECK_LE(compilation_unit_code_address, method_info->code_address); const uint32_t low_pc = dchecked_integral_cast( method_info->code_address + pc_offset - compilation_unit_code_address); stack_maps.emplace(low_pc, s); } // Create entries for the requested register based on stack map data. for (auto it = stack_maps.begin(); it != stack_maps.end(); it++) { const uint32_t low_pc = it->first; const uint32_t stack_map_index = it->second; const StackMap stack_map = code_info.GetStackMapAt(stack_map_index); auto next_it = it; next_it++; const uint32_t high_pc = next_it != stack_maps.end() ? next_it->first : method_info->code_address + method_info->code_size - compilation_unit_code_address; DCHECK_LE(low_pc, high_pc); if (low_pc == high_pc) { continue; // Ignore if the address range is empty. } // Check that the stack map is in the requested range. uint32_t dex_pc = stack_map.GetDexPc(); if (!(dex_pc_low <= dex_pc && dex_pc < dex_pc_high)) { // The variable is not in scope at this PC. Therefore omit the entry. // Note that this is different to None() entry which means in scope, but unknown location. continue; } // Find the location of the dex register. DexRegisterLocation reg_lo = DexRegisterLocation::None(); DexRegisterLocation reg_hi = DexRegisterLocation::None(); DCHECK_LT(stack_map_index, dex_register_maps.size()); DexRegisterMap dex_register_map = dex_register_maps[stack_map_index]; DCHECK(!dex_register_map.empty()); CodeItemDataAccessor accessor(*method_info->dex_file, method_info->code_item); reg_lo = dex_register_map[vreg]; if (is64bitValue) { reg_hi = dex_register_map[vreg + 1]; } // Add location entry for this address range. if (!variable_locations.empty() && variable_locations.back().reg_lo == reg_lo && variable_locations.back().reg_hi == reg_hi && variable_locations.back().high_pc == low_pc) { // Merge with the previous entry (extend its range). variable_locations.back().high_pc = high_pc; } else { variable_locations.push_back({low_pc, high_pc, reg_lo, reg_hi}); } } return variable_locations; } // Write table into .debug_loc which describes location of dex register. // The dex register might be valid only at some points and it might // move between machine registers and stack. static void WriteDebugLocEntry(const MethodDebugInfo* method_info, const std::vector& dex_register_maps, uint16_t vreg, bool is64bitValue, uint64_t compilation_unit_code_address, uint32_t dex_pc_low, uint32_t dex_pc_high, InstructionSet isa, dwarf::DebugInfoEntryWriter<>* debug_info, std::vector* debug_loc_buffer, std::vector* debug_ranges_buffer) { using Kind = DexRegisterLocation::Kind; if (method_info->code_info == nullptr || dex_register_maps.empty()) { return; } std::vector variable_locations = GetVariableLocations( method_info, dex_register_maps, vreg, is64bitValue, compilation_unit_code_address, dex_pc_low, dex_pc_high, isa); // Write .debug_loc entries. dwarf::Writer<> debug_loc(debug_loc_buffer); const size_t debug_loc_offset = debug_loc.size(); const bool is64bit = Is64BitInstructionSet(isa); std::vector expr_buffer; for (const VariableLocation& variable_location : variable_locations) { // Translate dex register location to DWARF expression. // Note that 64-bit value might be split to two distinct locations. // (for example, two 32-bit machine registers, or even stack and register) dwarf::Expression expr(&expr_buffer); DexRegisterLocation reg_lo = variable_location.reg_lo; DexRegisterLocation reg_hi = variable_location.reg_hi; for (int piece = 0; piece < (is64bitValue ? 2 : 1); piece++) { DexRegisterLocation reg_loc = (piece == 0 ? reg_lo : reg_hi); const Kind kind = reg_loc.GetKind(); const int32_t value = reg_loc.GetValue(); if (kind == Kind::kInStack) { // The stack offset is relative to SP. Make it relative to CFA. expr.WriteOpFbreg(value - method_info->frame_size_in_bytes); if (piece == 0 && reg_hi.GetKind() == Kind::kInStack && reg_hi.GetValue() == value + 4) { break; // the high word is correctly implied by the low word. } } else if (kind == Kind::kInRegister) { expr.WriteOpReg(GetDwarfCoreReg(isa, value).num()); if (piece == 0 && reg_hi.GetKind() == Kind::kInRegisterHigh && reg_hi.GetValue() == value) { break; // the high word is correctly implied by the low word. } } else if (kind == Kind::kInFpuRegister) { if ((isa == InstructionSet::kArm || isa == InstructionSet::kThumb2) && piece == 0 && reg_hi.GetKind() == Kind::kInFpuRegister && reg_hi.GetValue() == value + 1 && value % 2 == 0) { // Translate S register pair to D register (e.g. S4+S5 to D2). expr.WriteOpReg(Reg::ArmDp(value / 2).num()); break; } expr.WriteOpReg(GetDwarfFpReg(isa, value).num()); if (piece == 0 && reg_hi.GetKind() == Kind::kInFpuRegisterHigh && reg_hi.GetValue() == reg_lo.GetValue()) { break; // the high word is correctly implied by the low word. } } else if (kind == Kind::kConstant) { expr.WriteOpConsts(value); expr.WriteOpStackValue(); } else if (kind == Kind::kNone) { break; } else { // kInStackLargeOffset and kConstantLargeValue are hidden by GetKind(). // kInRegisterHigh and kInFpuRegisterHigh should be handled by // the special cases above and they should not occur alone. LOG(WARNING) << "Unexpected register location: " << kind << " (This can indicate either a bug in the dexer when generating" << " local variable information, or a bug in ART compiler." << " Please file a bug at go/art-bug)"; break; } if (is64bitValue) { // Write the marker which is needed by split 64-bit values. // This code is skipped by the special cases. expr.WriteOpPiece(4); } } if (expr.size() > 0) { if (is64bit) { debug_loc.PushUint64(variable_location.low_pc); debug_loc.PushUint64(variable_location.high_pc); } else { debug_loc.PushUint32(variable_location.low_pc); debug_loc.PushUint32(variable_location.high_pc); } // Write the expression. debug_loc.PushUint16(expr.size()); debug_loc.PushData(expr.data()); } else { // Do not generate .debug_loc if the location is not known. } } // Write end-of-list entry. if (is64bit) { debug_loc.PushUint64(0); debug_loc.PushUint64(0); } else { debug_loc.PushUint32(0); debug_loc.PushUint32(0); } // Write .debug_ranges entries. // This includes ranges where the variable is in scope but the location is not known. dwarf::Writer<> debug_ranges(debug_ranges_buffer); size_t debug_ranges_offset = debug_ranges.size(); for (size_t i = 0; i < variable_locations.size(); i++) { uint32_t low_pc = variable_locations[i].low_pc; uint32_t high_pc = variable_locations[i].high_pc; while (i + 1 < variable_locations.size() && variable_locations[i+1].low_pc == high_pc) { // Merge address range with the next entry. high_pc = variable_locations[++i].high_pc; } if (is64bit) { debug_ranges.PushUint64(low_pc); debug_ranges.PushUint64(high_pc); } else { debug_ranges.PushUint32(low_pc); debug_ranges.PushUint32(high_pc); } } // Write end-of-list entry. if (is64bit) { debug_ranges.PushUint64(0); debug_ranges.PushUint64(0); } else { debug_ranges.PushUint32(0); debug_ranges.PushUint32(0); } // Simple de-duplication - check whether this entry is same as the last one (or tail of it). size_t debug_ranges_entry_size = debug_ranges.size() - debug_ranges_offset; if (debug_ranges_offset >= debug_ranges_entry_size) { size_t previous_offset = debug_ranges_offset - debug_ranges_entry_size; if (memcmp(debug_ranges_buffer->data() + previous_offset, debug_ranges_buffer->data() + debug_ranges_offset, debug_ranges_entry_size) == 0) { // Remove what we have just written and use the last entry instead. debug_ranges_buffer->resize(debug_ranges_offset); debug_ranges_offset = previous_offset; } } // Write attributes to .debug_info. debug_info->WriteSecOffset(dwarf::DW_AT_location, debug_loc_offset); debug_info->WriteSecOffset(dwarf::DW_AT_start_scope, debug_ranges_offset); } } // namespace debug } // namespace art #endif // ART_COMPILER_DEBUG_ELF_DEBUG_LOC_WRITER_H_