//===-- DWARFDebugArangeSet.cpp ---------------------------------*- C++ -*-===// // // The LLVM Compiler Infrastructure // // This file is distributed under the University of Illinois Open Source // License. See LICENSE.TXT for details. // //===----------------------------------------------------------------------===// #include "DWARFDebugArangeSet.h" #include <assert.h> #include "lldb/Core/Stream.h" #include "SymbolFileDWARF.h" using namespace lldb_private; DWARFDebugArangeSet::DWARFDebugArangeSet() : m_offset(DW_INVALID_OFFSET), m_header(), m_arange_descriptors() { m_header.length = 0; m_header.version = 0; m_header.cu_offset = 0; m_header.addr_size = 0; m_header.seg_size = 0; } void DWARFDebugArangeSet::Clear() { m_offset = DW_INVALID_OFFSET; m_header.length = 0; m_header.version = 0; m_header.cu_offset = 0; m_header.addr_size = 0; m_header.seg_size = 0; m_arange_descriptors.clear(); } void DWARFDebugArangeSet::SetHeader ( uint16_t version, uint32_t cu_offset, uint8_t addr_size, uint8_t seg_size ) { m_header.version = version; m_header.cu_offset = cu_offset; m_header.addr_size = addr_size; m_header.seg_size = seg_size; } void DWARFDebugArangeSet::Compact() { if (m_arange_descriptors.empty()) return; // Iterate through all arange descriptors and combine any ranges that // overlap or have matching boundaries. The m_arange_descriptors are assumed // to be in ascending order after being built by adding descriptors // using the AddDescriptor method. uint32_t i = 0; while (i + 1 < m_arange_descriptors.size()) { if (m_arange_descriptors[i].end_address() >= m_arange_descriptors[i+1].address) { // The current range ends at or exceeds the start of the next address range. // Compute the max end address between the two and use that to make the new // length. const dw_addr_t max_end_addr = std::max(m_arange_descriptors[i].end_address(), m_arange_descriptors[i+1].end_address()); m_arange_descriptors[i].length = max_end_addr - m_arange_descriptors[i].address; // Now remove the next entry as it was just combined with the previous one. m_arange_descriptors.erase(m_arange_descriptors.begin()+i+1); } else { // Discontiguous address range, just proceed to the next one. ++i; } } } //---------------------------------------------------------------------- // Compare function DWARFDebugArangeSet::Descriptor structures //---------------------------------------------------------------------- static bool DescriptorLessThan (const DWARFDebugArangeSet::Descriptor& range1, const DWARFDebugArangeSet::Descriptor& range2) { return range1.address < range2.address; } //---------------------------------------------------------------------- // Add a range descriptor and keep things sorted so we can easily // compact the ranges before being saved or used. //---------------------------------------------------------------------- void DWARFDebugArangeSet::AddDescriptor(const DWARFDebugArangeSet::Descriptor& range) { if (m_arange_descriptors.empty()) { m_arange_descriptors.push_back(range); return; } DescriptorIter end = m_arange_descriptors.end(); DescriptorIter pos = lower_bound(m_arange_descriptors.begin(), end, range, DescriptorLessThan); const dw_addr_t range_end_addr = range.end_address(); if (pos != end) { const dw_addr_t found_end_addr = pos->end_address(); if (range.address < pos->address) { if (range_end_addr < pos->address) { // Non-contiguous entries, add this one before the found entry m_arange_descriptors.insert(pos, range); } else if (range_end_addr == pos->address) { // The top end of 'range' is the lower end of the entry // pointed to by 'pos'. We can combine range with the // entry we found by setting the starting address and // increasing the length since they don't overlap. pos->address = range.address; pos->length += range.length; } else { // We can combine these two and make sure the largest end // address is used to make end address. pos->address = range.address; pos->length = std::max(found_end_addr, range_end_addr) - pos->address; } } else if (range.address == pos->address) { pos->length = std::max(pos->length, range.length); } } else { // NOTE: 'pos' points to entry past the end which is ok for insert, // don't use otherwise!!! const dw_addr_t max_addr = m_arange_descriptors.back().end_address(); if (max_addr < range.address) { // Non-contiguous entries, add this one before the found entry m_arange_descriptors.insert(pos, range); } else if (max_addr == range.address) { m_arange_descriptors.back().length += range.length; } else { m_arange_descriptors.back().length = std::max(max_addr, range_end_addr) - m_arange_descriptors.back().address; } } } bool DWARFDebugArangeSet::Extract(const DataExtractor &data, lldb::offset_t *offset_ptr) { if (data.ValidOffset(*offset_ptr)) { m_arange_descriptors.clear(); m_offset = *offset_ptr; // 7.20 Address Range Table // // Each set of entries in the table of address ranges contained in // the .debug_aranges section begins with a header consisting of: a // 4-byte length containing the length of the set of entries for this // compilation unit, not including the length field itself; a 2-byte // version identifier containing the value 2 for DWARF Version 2; a // 4-byte offset into the.debug_infosection; a 1-byte unsigned integer // containing the size in bytes of an address (or the offset portion of // an address for segmented addressing) on the target system; and a // 1-byte unsigned integer containing the size in bytes of a segment // descriptor on the target system. This header is followed by a series // of tuples. Each tuple consists of an address and a length, each in // the size appropriate for an address on the target architecture. m_header.length = data.GetU32(offset_ptr); m_header.version = data.GetU16(offset_ptr); m_header.cu_offset = data.GetU32(offset_ptr); m_header.addr_size = data.GetU8(offset_ptr); m_header.seg_size = data.GetU8(offset_ptr); // The first tuple following the header in each set begins at an offset // that is a multiple of the size of a single tuple (that is, twice the // size of an address). The header is padded, if necessary, to the // appropriate boundary. const uint32_t header_size = *offset_ptr - m_offset; const uint32_t tuple_size = m_header.addr_size << 1; uint32_t first_tuple_offset = 0; while (first_tuple_offset < header_size) first_tuple_offset += tuple_size; *offset_ptr = m_offset + first_tuple_offset; Descriptor arangeDescriptor; assert(sizeof(arangeDescriptor.address) == sizeof(arangeDescriptor.length)); assert(sizeof(arangeDescriptor.address) >= m_header.addr_size); while (data.ValidOffset(*offset_ptr)) { arangeDescriptor.address = data.GetMaxU64(offset_ptr, m_header.addr_size); arangeDescriptor.length = data.GetMaxU64(offset_ptr, m_header.addr_size); // Each set of tuples is terminated by a 0 for the address and 0 // for the length. if (arangeDescriptor.address || arangeDescriptor.length) m_arange_descriptors.push_back(arangeDescriptor); else break; // We are done if we get a zero address and length } return !m_arange_descriptors.empty(); } return false; } dw_offset_t DWARFDebugArangeSet::GetOffsetOfNextEntry() const { return m_offset + m_header.length + 4; } void DWARFDebugArangeSet::Dump(Stream *s) const { s->Printf("Address Range Header: length = 0x%8.8x, version = 0x%4.4x, cu_offset = 0x%8.8x, addr_size = 0x%2.2x, seg_size = 0x%2.2x\n", m_header.length ,m_header.version, m_header.cu_offset, m_header.addr_size, m_header.seg_size); const uint32_t hex_width = m_header.addr_size * 2; DescriptorConstIter pos; DescriptorConstIter end = m_arange_descriptors.end(); for (pos = m_arange_descriptors.begin(); pos != end; ++pos) s->Printf("[0x%*.*" PRIx64 " - 0x%*.*" PRIx64 ")\n", hex_width, hex_width, pos->address, hex_width, hex_width, pos->end_address()); } class DescriptorContainsAddress { public: DescriptorContainsAddress (dw_addr_t address) : m_address(address) {} bool operator() (const DWARFDebugArangeSet::Descriptor& desc) const { return (m_address >= desc.address) && (m_address < (desc.address + desc.length)); } private: const dw_addr_t m_address; }; dw_offset_t DWARFDebugArangeSet::FindAddress(dw_addr_t address) const { DescriptorConstIter end = m_arange_descriptors.end(); DescriptorConstIter pos = std::find_if( m_arange_descriptors.begin(), end, // Range DescriptorContainsAddress(address));// Predicate if (pos != end) return m_header.cu_offset; return DW_INVALID_OFFSET; }