llvm-project/lldb/source/Symbol/LineTable.cpp

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//===-- LineTable.cpp -------------------------------------------*- C++ -*-===//
//
// 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/Symbol/LineTable.h"
#include "lldb/Core/Address.h"
#include "lldb/Core/Module.h"
#include "lldb/Core/Section.h"
#include "lldb/Symbol/CompileUnit.h"
#include "lldb/Utility/Stream.h"
#include <algorithm>
using namespace lldb;
using namespace lldb_private;
// LineTable constructor
LineTable::LineTable(CompileUnit *comp_unit)
: m_comp_unit(comp_unit), m_entries() {}
// Destructor
LineTable::~LineTable() {}
void LineTable::InsertLineEntry(lldb::addr_t file_addr, uint32_t line,
uint16_t column, uint16_t file_idx,
bool is_start_of_statement,
bool is_start_of_basic_block,
bool is_prologue_end, bool is_epilogue_begin,
bool is_terminal_entry) {
Entry entry(file_addr, line, column, file_idx, is_start_of_statement,
is_start_of_basic_block, is_prologue_end, is_epilogue_begin,
is_terminal_entry);
LineTable::Entry::LessThanBinaryPredicate less_than_bp(this);
entry_collection::iterator pos =
llvm::upper_bound(m_entries, entry, less_than_bp);
// Stream s(stdout);
// s << "\n\nBefore:\n";
// Dump (&s, Address::DumpStyleFileAddress);
m_entries.insert(pos, entry);
// s << "After:\n";
// Dump (&s, Address::DumpStyleFileAddress);
}
LineSequence::LineSequence() {}
void LineTable::LineSequenceImpl::Clear() { m_entries.clear(); }
LineSequence *LineTable::CreateLineSequenceContainer() {
return new LineTable::LineSequenceImpl();
}
void LineTable::AppendLineEntryToSequence(
LineSequence *sequence, lldb::addr_t file_addr, uint32_t line,
uint16_t column, uint16_t file_idx, bool is_start_of_statement,
bool is_start_of_basic_block, bool is_prologue_end, bool is_epilogue_begin,
bool is_terminal_entry) {
assert(sequence != nullptr);
LineSequenceImpl *seq = reinterpret_cast<LineSequenceImpl *>(sequence);
Entry entry(file_addr, line, column, file_idx, is_start_of_statement,
is_start_of_basic_block, is_prologue_end, is_epilogue_begin,
is_terminal_entry);
entry_collection &entries = seq->m_entries;
// Replace the last entry if the address is the same, otherwise append it. If
// we have multiple line entries at the same address, this indicates illegal
// DWARF so this "fixes" the line table to be correct. If not fixed this can
// cause a line entry's address that when resolved back to a symbol context,
// could resolve to a different line entry. We really want a
// 1 to 1 mapping
// here to avoid these kinds of inconsistencies. We will need tor revisit
// this if the DWARF line tables are updated to allow multiple entries at the
// same address legally.
if (!entries.empty() && entries.back().file_addr == file_addr) {
// GCC don't use the is_prologue_end flag to mark the first instruction
// after the prologue.
// Instead of it it is issuing a line table entry for the first instruction
// of the prologue and one for the first instruction after the prologue. If
// the size of the prologue is 0 instruction then the 2 line entry will
// have the same file address. Removing it will remove our ability to
// properly detect the location of the end of prologe so we set the
// prologue_end flag to preserve this information (setting the prologue_end
// flag for an entry what is after the prologue end don't have any effect)
entry.is_prologue_end = entry.file_idx == entries.back().file_idx;
entries.back() = entry;
} else
entries.push_back(entry);
}
void LineTable::InsertSequence(LineSequence *sequence) {
assert(sequence != nullptr);
LineSequenceImpl *seq = reinterpret_cast<LineSequenceImpl *>(sequence);
if (seq->m_entries.empty())
return;
Entry &entry = seq->m_entries.front();
// If the first entry address in this sequence is greater than or equal to
// the address of the last item in our entry collection, just append.
if (m_entries.empty() ||
!Entry::EntryAddressLessThan(entry, m_entries.back())) {
m_entries.insert(m_entries.end(), seq->m_entries.begin(),
seq->m_entries.end());
return;
}
// Otherwise, find where this belongs in the collection
entry_collection::iterator begin_pos = m_entries.begin();
entry_collection::iterator end_pos = m_entries.end();
LineTable::Entry::LessThanBinaryPredicate less_than_bp(this);
entry_collection::iterator pos =
upper_bound(begin_pos, end_pos, entry, less_than_bp);
// We should never insert a sequence in the middle of another sequence
if (pos != begin_pos) {
while (pos < end_pos && !((pos - 1)->is_terminal_entry))
pos++;
}
#ifndef NDEBUG
// If we aren't inserting at the beginning, the previous entry should
// terminate a sequence.
if (pos != begin_pos) {
entry_collection::iterator prev_pos = pos - 1;
assert(prev_pos->is_terminal_entry);
}
#endif
m_entries.insert(pos, seq->m_entries.begin(), seq->m_entries.end());
}
LineTable::Entry::LessThanBinaryPredicate::LessThanBinaryPredicate(
LineTable *line_table)
: m_line_table(line_table) {}
bool LineTable::Entry::LessThanBinaryPredicate::
operator()(const LineTable::Entry &a, const LineTable::Entry &b) const {
#define LT_COMPARE(a, b) \
if (a != b) \
return a < b
LT_COMPARE(a.file_addr, b.file_addr);
// b and a reversed on purpose below.
LT_COMPARE(b.is_terminal_entry, a.is_terminal_entry);
LT_COMPARE(a.line, b.line);
LT_COMPARE(a.column, b.column);
LT_COMPARE(a.is_start_of_statement, b.is_start_of_statement);
LT_COMPARE(a.is_start_of_basic_block, b.is_start_of_basic_block);
// b and a reversed on purpose below.
LT_COMPARE(b.is_prologue_end, a.is_prologue_end);
LT_COMPARE(a.is_epilogue_begin, b.is_epilogue_begin);
LT_COMPARE(a.file_idx, b.file_idx);
return false;
#undef LT_COMPARE
}
uint32_t LineTable::GetSize() const { return m_entries.size(); }
bool LineTable::GetLineEntryAtIndex(uint32_t idx, LineEntry &line_entry) {
if (idx < m_entries.size()) {
ConvertEntryAtIndexToLineEntry(idx, line_entry);
return true;
}
line_entry.Clear();
return false;
}
bool LineTable::FindLineEntryByAddress(const Address &so_addr,
LineEntry &line_entry,
uint32_t *index_ptr) {
if (index_ptr != nullptr)
*index_ptr = UINT32_MAX;
bool success = false;
if (so_addr.GetModule().get() == m_comp_unit->GetModule().get()) {
Entry search_entry;
search_entry.file_addr = so_addr.GetFileAddress();
if (search_entry.file_addr != LLDB_INVALID_ADDRESS) {
entry_collection::const_iterator begin_pos = m_entries.begin();
entry_collection::const_iterator end_pos = m_entries.end();
entry_collection::const_iterator pos = lower_bound(
begin_pos, end_pos, search_entry, Entry::EntryAddressLessThan);
if (pos != end_pos) {
if (pos != begin_pos) {
if (pos->file_addr != search_entry.file_addr)
--pos;
else if (pos->file_addr == search_entry.file_addr) {
// If this is a termination entry, it shouldn't match since entries
// with the "is_terminal_entry" member set to true are termination
// entries that define the range for the previous entry.
if (pos->is_terminal_entry) {
// The matching entry is a terminal entry, so we skip ahead to
// the next entry to see if there is another entry following this
// one whose section/offset matches.
++pos;
if (pos != end_pos) {
if (pos->file_addr != search_entry.file_addr)
pos = end_pos;
}
}
if (pos != end_pos) {
// While in the same section/offset backup to find the first line
// entry that matches the address in case there are multiple
while (pos != begin_pos) {
entry_collection::const_iterator prev_pos = pos - 1;
if (prev_pos->file_addr == search_entry.file_addr &&
prev_pos->is_terminal_entry == false)
--pos;
else
break;
}
}
}
}
else
{
// There might be code in the containing objfile before the first
// line table entry. Make sure that does not get considered part of
// the first line table entry.
if (pos->file_addr > so_addr.GetFileAddress())
return false;
}
// Make sure we have a valid match and that the match isn't a
// terminating entry for a previous line...
if (pos != end_pos && pos->is_terminal_entry == false) {
uint32_t match_idx = std::distance(begin_pos, pos);
success = ConvertEntryAtIndexToLineEntry(match_idx, line_entry);
if (index_ptr != nullptr && success)
*index_ptr = match_idx;
}
}
}
}
return success;
}
bool LineTable::ConvertEntryAtIndexToLineEntry(uint32_t idx,
LineEntry &line_entry) {
if (idx >= m_entries.size())
return false;
const Entry &entry = m_entries[idx];
ModuleSP module_sp(m_comp_unit->GetModule());
if (!module_sp)
return false;
addr_t file_addr = entry.file_addr;
// A terminal entry can point outside of a module or a section. Decrement the
// address to ensure it resolves correctly.
if (entry.is_terminal_entry)
--file_addr;
if (!module_sp->ResolveFileAddress(file_addr,
line_entry.range.GetBaseAddress()))
return false;
// Now undo the decrement above.
if (entry.is_terminal_entry)
line_entry.range.GetBaseAddress().Slide(1);
if (!entry.is_terminal_entry && idx + 1 < m_entries.size())
line_entry.range.SetByteSize(m_entries[idx + 1].file_addr -
entry.file_addr);
else
line_entry.range.SetByteSize(0);
line_entry.file =
m_comp_unit->GetSupportFiles().GetFileSpecAtIndex(entry.file_idx);
line_entry.original_file =
m_comp_unit->GetSupportFiles().GetFileSpecAtIndex(entry.file_idx);
line_entry.line = entry.line;
line_entry.column = entry.column;
line_entry.is_start_of_statement = entry.is_start_of_statement;
line_entry.is_start_of_basic_block = entry.is_start_of_basic_block;
line_entry.is_prologue_end = entry.is_prologue_end;
line_entry.is_epilogue_begin = entry.is_epilogue_begin;
line_entry.is_terminal_entry = entry.is_terminal_entry;
return true;
}
uint32_t LineTable::FindLineEntryIndexByFileIndex(
uint32_t start_idx, const std::vector<uint32_t> &file_indexes,
uint32_t line, bool exact, LineEntry *line_entry_ptr) {
const size_t count = m_entries.size();
size_t best_match = UINT32_MAX;
for (size_t idx = start_idx; idx < count; ++idx) {
// Skip line table rows that terminate the previous row (is_terminal_entry
// is non-zero)
if (m_entries[idx].is_terminal_entry)
continue;
if (llvm::find(file_indexes, m_entries[idx].file_idx) == file_indexes.end())
continue;
// Exact match always wins. Otherwise try to find the closest line > the
// desired line.
// FIXME: Maybe want to find the line closest before and the line closest
// after and
// if they're not in the same function, don't return a match.
if (m_entries[idx].line < line) {
continue;
} else if (m_entries[idx].line == line) {
if (line_entry_ptr)
ConvertEntryAtIndexToLineEntry(idx, *line_entry_ptr);
return idx;
} else if (!exact) {
if (best_match == UINT32_MAX)
best_match = idx;
else if (m_entries[idx].line < m_entries[best_match].line)
best_match = idx;
}
}
if (best_match != UINT32_MAX) {
if (line_entry_ptr)
ConvertEntryAtIndexToLineEntry(best_match, *line_entry_ptr);
return best_match;
}
return UINT32_MAX;
}
uint32_t LineTable::FindLineEntryIndexByFileIndex(uint32_t start_idx,
uint32_t file_idx,
uint32_t line, bool exact,
LineEntry *line_entry_ptr) {
const size_t count = m_entries.size();
size_t best_match = UINT32_MAX;
for (size_t idx = start_idx; idx < count; ++idx) {
// Skip line table rows that terminate the previous row (is_terminal_entry
// is non-zero)
if (m_entries[idx].is_terminal_entry)
continue;
if (m_entries[idx].file_idx != file_idx)
continue;
// Exact match always wins. Otherwise try to find the closest line > the
// desired line.
// FIXME: Maybe want to find the line closest before and the line closest
// after and
// if they're not in the same function, don't return a match.
if (m_entries[idx].line < line) {
continue;
} else if (m_entries[idx].line == line) {
if (line_entry_ptr)
ConvertEntryAtIndexToLineEntry(idx, *line_entry_ptr);
return idx;
} else if (!exact) {
if (best_match == UINT32_MAX)
best_match = idx;
else if (m_entries[idx].line < m_entries[best_match].line)
best_match = idx;
}
}
if (best_match != UINT32_MAX) {
if (line_entry_ptr)
ConvertEntryAtIndexToLineEntry(best_match, *line_entry_ptr);
return best_match;
}
return UINT32_MAX;
}
size_t LineTable::FineLineEntriesForFileIndex(uint32_t file_idx, bool append,
SymbolContextList &sc_list) {
if (!append)
sc_list.Clear();
size_t num_added = 0;
const size_t count = m_entries.size();
if (count > 0) {
SymbolContext sc(m_comp_unit);
for (size_t idx = 0; idx < count; ++idx) {
// Skip line table rows that terminate the previous row
// (is_terminal_entry is non-zero)
if (m_entries[idx].is_terminal_entry)
continue;
if (m_entries[idx].file_idx == file_idx) {
if (ConvertEntryAtIndexToLineEntry(idx, sc.line_entry)) {
++num_added;
sc_list.Append(sc);
}
}
}
}
return num_added;
}
void LineTable::Dump(Stream *s, Target *target, Address::DumpStyle style,
Address::DumpStyle fallback_style, bool show_line_ranges) {
const size_t count = m_entries.size();
LineEntry line_entry;
FileSpec prev_file;
for (size_t idx = 0; idx < count; ++idx) {
ConvertEntryAtIndexToLineEntry(idx, line_entry);
line_entry.Dump(s, target, prev_file != line_entry.original_file, style,
fallback_style, show_line_ranges);
s->EOL();
prev_file = line_entry.original_file;
}
}
void LineTable::GetDescription(Stream *s, Target *target,
DescriptionLevel level) {
const size_t count = m_entries.size();
LineEntry line_entry;
for (size_t idx = 0; idx < count; ++idx) {
ConvertEntryAtIndexToLineEntry(idx, line_entry);
line_entry.GetDescription(s, level, m_comp_unit, target, true);
s->EOL();
}
}
size_t LineTable::GetContiguousFileAddressRanges(FileAddressRanges &file_ranges,
bool append) {
if (!append)
file_ranges.Clear();
const size_t initial_count = file_ranges.GetSize();
const size_t count = m_entries.size();
LineEntry line_entry;
FileAddressRanges::Entry range(LLDB_INVALID_ADDRESS, 0);
for (size_t idx = 0; idx < count; ++idx) {
const Entry &entry = m_entries[idx];
if (entry.is_terminal_entry) {
if (range.GetRangeBase() != LLDB_INVALID_ADDRESS) {
range.SetRangeEnd(entry.file_addr);
file_ranges.Append(range);
range.Clear(LLDB_INVALID_ADDRESS);
}
} else if (range.GetRangeBase() == LLDB_INVALID_ADDRESS) {
range.SetRangeBase(entry.file_addr);
}
}
return file_ranges.GetSize() - initial_count;
}
LineTable *LineTable::LinkLineTable(const FileRangeMap &file_range_map) {
std::unique_ptr<LineTable> line_table_up(new LineTable(m_comp_unit));
LineSequenceImpl sequence;
const size_t count = m_entries.size();
LineEntry line_entry;
const FileRangeMap::Entry *file_range_entry = nullptr;
const FileRangeMap::Entry *prev_file_range_entry = nullptr;
lldb::addr_t prev_file_addr = LLDB_INVALID_ADDRESS;
bool prev_entry_was_linked = false;
bool range_changed = false;
for (size_t idx = 0; idx < count; ++idx) {
const Entry &entry = m_entries[idx];
const bool end_sequence = entry.is_terminal_entry;
const lldb::addr_t lookup_file_addr =
entry.file_addr - (end_sequence ? 1 : 0);
if (file_range_entry == nullptr ||
!file_range_entry->Contains(lookup_file_addr)) {
prev_file_range_entry = file_range_entry;
file_range_entry = file_range_map.FindEntryThatContains(lookup_file_addr);
range_changed = true;
}
lldb::addr_t prev_end_entry_linked_file_addr = LLDB_INVALID_ADDRESS;
lldb::addr_t entry_linked_file_addr = LLDB_INVALID_ADDRESS;
bool terminate_previous_entry = false;
if (file_range_entry) {
entry_linked_file_addr = entry.file_addr -
file_range_entry->GetRangeBase() +
file_range_entry->data;
// Determine if we need to terminate the previous entry when the previous
// entry was not contiguous with this one after being linked.
if (range_changed && prev_file_range_entry) {
prev_end_entry_linked_file_addr =
std::min<lldb::addr_t>(entry.file_addr,
prev_file_range_entry->GetRangeEnd()) -
prev_file_range_entry->GetRangeBase() + prev_file_range_entry->data;
if (prev_end_entry_linked_file_addr != entry_linked_file_addr)
terminate_previous_entry = prev_entry_was_linked;
}
} else if (prev_entry_was_linked) {
// This entry doesn't have a remapping and it needs to be removed. Watch
// out in case we need to terminate a previous entry needs to be
// terminated now that one line entry in a sequence is not longer valid.
if (!sequence.m_entries.empty() &&
!sequence.m_entries.back().is_terminal_entry) {
terminate_previous_entry = true;
}
}
if (terminate_previous_entry && !sequence.m_entries.empty()) {
assert(prev_file_addr != LLDB_INVALID_ADDRESS);
UNUSED_IF_ASSERT_DISABLED(prev_file_addr);
sequence.m_entries.push_back(sequence.m_entries.back());
if (prev_end_entry_linked_file_addr == LLDB_INVALID_ADDRESS)
prev_end_entry_linked_file_addr =
std::min<lldb::addr_t>(entry.file_addr,
prev_file_range_entry->GetRangeEnd()) -
prev_file_range_entry->GetRangeBase() + prev_file_range_entry->data;
sequence.m_entries.back().file_addr = prev_end_entry_linked_file_addr;
sequence.m_entries.back().is_terminal_entry = true;
// Append the sequence since we just terminated the previous one
line_table_up->InsertSequence(&sequence);
sequence.Clear();
}
// Now link the current entry
if (file_range_entry) {
// This entry has an address remapping and it needs to have its address
// relinked
sequence.m_entries.push_back(entry);
sequence.m_entries.back().file_addr = entry_linked_file_addr;
}
// If we have items in the sequence and the last entry is a terminal entry,
// insert this sequence into our new line table.
if (!sequence.m_entries.empty() &&
sequence.m_entries.back().is_terminal_entry) {
line_table_up->InsertSequence(&sequence);
sequence.Clear();
prev_entry_was_linked = false;
} else {
prev_entry_was_linked = file_range_entry != nullptr;
}
prev_file_addr = entry.file_addr;
range_changed = false;
}
if (line_table_up->m_entries.empty())
return nullptr;
return line_table_up.release();
}