//===-- BreakpointBase.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 "BreakpointBase.h" #include "DAP.h" #include "JSONUtils.h" #include "llvm/ADT/StringExtras.h" using namespace lldb_dap; BreakpointBase::BreakpointBase(const llvm::json::Object &obj) : condition(std::string(GetString(obj, "condition"))), hitCondition(std::string(GetString(obj, "hitCondition"))), logMessage(std::string(GetString(obj, "logMessage"))) {} void BreakpointBase::SetCondition() { bp.SetCondition(condition.c_str()); } void BreakpointBase::SetHitCondition() { uint64_t hitCount = 0; if (llvm::to_integer(hitCondition, hitCount)) bp.SetIgnoreCount(hitCount - 1); } lldb::SBError BreakpointBase::AppendLogMessagePart(llvm::StringRef part, bool is_expr) { if (is_expr) { logMessageParts.emplace_back(part, is_expr); } else { std::string formatted; lldb::SBError error = FormatLogText(part, formatted); if (error.Fail()) return error; logMessageParts.emplace_back(formatted, is_expr); } return lldb::SBError(); } // TODO: consolidate this code with the implementation in // FormatEntity::ParseInternal(). lldb::SBError BreakpointBase::FormatLogText(llvm::StringRef text, std::string &formatted) { lldb::SBError error; while (!text.empty()) { size_t backslash_pos = text.find_first_of('\\'); if (backslash_pos == std::string::npos) { formatted += text.str(); return error; } formatted += text.substr(0, backslash_pos).str(); // Skip the characters before and including '\'. text = text.drop_front(backslash_pos + 1); if (text.empty()) { error.SetErrorString( "'\\' character was not followed by another character"); return error; } const char desens_char = text[0]; text = text.drop_front(); // Skip the desensitized char character switch (desens_char) { case 'a': formatted.push_back('\a'); break; case 'b': formatted.push_back('\b'); break; case 'f': formatted.push_back('\f'); break; case 'n': formatted.push_back('\n'); break; case 'r': formatted.push_back('\r'); break; case 't': formatted.push_back('\t'); break; case 'v': formatted.push_back('\v'); break; case '\'': formatted.push_back('\''); break; case '\\': formatted.push_back('\\'); break; case '0': // 1 to 3 octal chars { if (text.empty()) { error.SetErrorString("missing octal number following '\\0'"); return error; } // Make a string that can hold onto the initial zero char, up to 3 // octal digits, and a terminating NULL. char oct_str[5] = {0, 0, 0, 0, 0}; size_t i; for (i = 0; i < text.size() && i < 4 && (text[i] >= '0' && text[i] <= '7'); ++i) { oct_str[i] = text[i]; } text = text.drop_front(i); unsigned long octal_value = ::strtoul(oct_str, nullptr, 8); if (octal_value <= UINT8_MAX) { formatted.push_back((char)octal_value); } else { error.SetErrorString("octal number is larger than a single byte"); return error; } } break; case 'x': { if (text.empty()) { error.SetErrorString("missing hex number following '\\x'"); return error; } // hex number in the text if (isxdigit(text[0])) { // Make a string that can hold onto two hex chars plus a // NULL terminator char hex_str[3] = {0, 0, 0}; hex_str[0] = text[0]; text = text.drop_front(); if (!text.empty() && isxdigit(text[0])) { hex_str[1] = text[0]; text = text.drop_front(); } unsigned long hex_value = strtoul(hex_str, nullptr, 16); if (hex_value <= UINT8_MAX) { formatted.push_back((char)hex_value); } else { error.SetErrorString("hex number is larger than a single byte"); return error; } } else { formatted.push_back(desens_char); } break; } default: // Just desensitize any other character by just printing what came // after the '\' formatted.push_back(desens_char); break; } } return error; } // logMessage will be divided into array of LogMessagePart as two kinds: // 1. raw print text message, and // 2. interpolated expression for evaluation which is inside matching curly // braces. // // The function tries to parse logMessage into a list of LogMessageParts // for easy later access in BreakpointHitCallback. void BreakpointBase::SetLogMessage() { logMessageParts.clear(); // Contains unmatched open curly braces indices. std::vector unmatched_curly_braces; // Contains all matched curly braces in logMessage. // Loop invariant: matched_curly_braces_ranges are sorted by start index in // ascending order without any overlap between them. std::vector> matched_curly_braces_ranges; lldb::SBError error; // Part1 - parse matched_curly_braces_ranges. // locating all curly braced expression ranges in logMessage. // The algorithm takes care of nested and imbalanced curly braces. for (size_t i = 0; i < logMessage.size(); ++i) { if (logMessage[i] == '{') { unmatched_curly_braces.push_back(i); } else if (logMessage[i] == '}') { if (unmatched_curly_braces.empty()) // Nothing to match. continue; int last_unmatched_index = unmatched_curly_braces.back(); unmatched_curly_braces.pop_back(); // Erase any matched ranges included in the new match. while (!matched_curly_braces_ranges.empty()) { assert(matched_curly_braces_ranges.back().first != last_unmatched_index && "How can a curley brace be matched twice?"); if (matched_curly_braces_ranges.back().first < last_unmatched_index) break; // This is a nested range let's earse it. assert((size_t)matched_curly_braces_ranges.back().second < i); matched_curly_braces_ranges.pop_back(); } // Assert invariant. assert(matched_curly_braces_ranges.empty() || matched_curly_braces_ranges.back().first < last_unmatched_index); matched_curly_braces_ranges.emplace_back(last_unmatched_index, i); } } // Part2 - parse raw text and expresions parts. // All expression ranges have been parsed in matched_curly_braces_ranges. // The code below uses matched_curly_braces_ranges to divide logMessage // into raw text parts and expression parts. int last_raw_text_start = 0; for (const std::pair &curly_braces_range : matched_curly_braces_ranges) { // Raw text before open curly brace. assert(curly_braces_range.first >= last_raw_text_start); size_t raw_text_len = curly_braces_range.first - last_raw_text_start; if (raw_text_len > 0) { error = AppendLogMessagePart( llvm::StringRef(logMessage.c_str() + last_raw_text_start, raw_text_len), /*is_expr=*/false); if (error.Fail()) { NotifyLogMessageError(error.GetCString()); return; } } // Expression between curly braces. assert(curly_braces_range.second > curly_braces_range.first); size_t expr_len = curly_braces_range.second - curly_braces_range.first - 1; error = AppendLogMessagePart( llvm::StringRef(logMessage.c_str() + curly_braces_range.first + 1, expr_len), /*is_expr=*/true); if (error.Fail()) { NotifyLogMessageError(error.GetCString()); return; } last_raw_text_start = curly_braces_range.second + 1; } // Trailing raw text after close curly brace. assert(last_raw_text_start >= 0); if (logMessage.size() > (size_t)last_raw_text_start) { error = AppendLogMessagePart( llvm::StringRef(logMessage.c_str() + last_raw_text_start, logMessage.size() - last_raw_text_start), /*is_expr=*/false); if (error.Fail()) { NotifyLogMessageError(error.GetCString()); return; } } bp.SetCallback(BreakpointBase::BreakpointHitCallback, this); } void BreakpointBase::NotifyLogMessageError(llvm::StringRef error) { std::string message = "Log message has error: "; message += error; g_dap.SendOutput(OutputType::Console, message); } /*static*/ bool BreakpointBase::BreakpointHitCallback( void *baton, lldb::SBProcess &process, lldb::SBThread &thread, lldb::SBBreakpointLocation &location) { if (!baton) return true; BreakpointBase *bp = (BreakpointBase *)baton; lldb::SBFrame frame = thread.GetSelectedFrame(); std::string output; for (const BreakpointBase::LogMessagePart &messagePart : bp->logMessageParts) { if (messagePart.is_expr) { // Try local frame variables first before fall back to expression // evaluation const std::string &expr_str = messagePart.text; const char *expr = expr_str.c_str(); lldb::SBValue value = frame.GetValueForVariablePath(expr, lldb::eDynamicDontRunTarget); if (value.GetError().Fail()) value = frame.EvaluateExpression(expr); output += VariableDescription(value).display_value; } else { output += messagePart.text; } } if (!output.empty() && output.back() != '\n') output.push_back('\n'); // Ensure log message has line break. g_dap.SendOutput(OutputType::Console, output.c_str()); // Do not stop. return false; } void BreakpointBase::UpdateBreakpoint(const BreakpointBase &request_bp) { if (condition != request_bp.condition) { condition = request_bp.condition; SetCondition(); } if (hitCondition != request_bp.hitCondition) { hitCondition = request_bp.hitCondition; SetHitCondition(); } if (logMessage != request_bp.logMessage) { logMessage = request_bp.logMessage; SetLogMessage(); } } const char *BreakpointBase::GetBreakpointLabel() { // Breakpoints in LLDB can have names added to them which are kind of like // labels or categories. All breakpoints that are set through the IDE UI get // sent through the various DAP set*Breakpoint packets, and these // breakpoints will be labeled with this name so if breakpoint update events // come in for breakpoints that the IDE doesn't know about, like if a // breakpoint is set manually using the debugger console, we won't report any // updates on them and confused the IDE. This function gets called by all of // the breakpoint classes after they set breakpoints to mark a breakpoint as // a UI breakpoint. We can later check a lldb::SBBreakpoint object that comes // in via LLDB breakpoint changed events and check the breakpoint by calling // "bool lldb::SBBreakpoint::MatchesName(const char *)" to check if a // breakpoint in one of the UI breakpoints that we should report changes for. return "dap"; }