//===-- Target.h ------------------------------------------------*- 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 // //===----------------------------------------------------------------------===// #ifndef LLDB_TARGET_TARGET_H #define LLDB_TARGET_TARGET_H #include #include #include #include #include #include "lldb/Breakpoint/BreakpointList.h" #include "lldb/Breakpoint/BreakpointName.h" #include "lldb/Breakpoint/WatchpointList.h" #include "lldb/Core/Architecture.h" #include "lldb/Core/Disassembler.h" #include "lldb/Core/ModuleList.h" #include "lldb/Core/StructuredDataImpl.h" #include "lldb/Core/UserSettingsController.h" #include "lldb/Expression/Expression.h" #include "lldb/Host/ProcessLaunchInfo.h" #include "lldb/Symbol/TypeSystem.h" #include "lldb/Target/ExecutionContextScope.h" #include "lldb/Target/PathMappingList.h" #include "lldb/Target/SectionLoadHistory.h" #include "lldb/Target/Statistics.h" #include "lldb/Target/ThreadSpec.h" #include "lldb/Utility/ArchSpec.h" #include "lldb/Utility/Broadcaster.h" #include "lldb/Utility/LLDBAssert.h" #include "lldb/Utility/Timeout.h" #include "lldb/lldb-public.h" namespace lldb_private { OptionEnumValues GetDynamicValueTypes(); enum InlineStrategy { eInlineBreakpointsNever = 0, eInlineBreakpointsHeaders, eInlineBreakpointsAlways }; enum LoadScriptFromSymFile { eLoadScriptFromSymFileTrue, eLoadScriptFromSymFileFalse, eLoadScriptFromSymFileWarn }; enum LoadCWDlldbinitFile { eLoadCWDlldbinitTrue, eLoadCWDlldbinitFalse, eLoadCWDlldbinitWarn }; enum ImportStdModule { eImportStdModuleFalse, eImportStdModuleFallback, eImportStdModuleTrue, }; enum DynamicClassInfoHelper { eDynamicClassInfoHelperAuto, eDynamicClassInfoHelperRealizedClassesStruct, eDynamicClassInfoHelperCopyRealizedClassList, eDynamicClassInfoHelperGetRealizedClassList, }; class TargetExperimentalProperties : public Properties { public: TargetExperimentalProperties(); }; class TargetProperties : public Properties { public: TargetProperties(Target *target); ~TargetProperties() override; ArchSpec GetDefaultArchitecture() const; void SetDefaultArchitecture(const ArchSpec &arch); bool GetMoveToNearestCode() const; lldb::DynamicValueType GetPreferDynamicValue() const; bool SetPreferDynamicValue(lldb::DynamicValueType d); bool GetPreloadSymbols() const; void SetPreloadSymbols(bool b); bool GetDisableASLR() const; void SetDisableASLR(bool b); bool GetInheritTCC() const; void SetInheritTCC(bool b); bool GetDetachOnError() const; void SetDetachOnError(bool b); bool GetDisableSTDIO() const; void SetDisableSTDIO(bool b); const char *GetDisassemblyFlavor() const; InlineStrategy GetInlineStrategy() const; llvm::StringRef GetArg0() const; void SetArg0(llvm::StringRef arg); bool GetRunArguments(Args &args) const; void SetRunArguments(const Args &args); // Get the whole environment including the platform inherited environment and // the target specific environment, excluding the unset environment variables. Environment GetEnvironment() const; // Get the platform inherited environment, excluding the unset environment // variables. Environment GetInheritedEnvironment() const; // Get the target specific environment only, without the platform inherited // environment. Environment GetTargetEnvironment() const; // Set the target specific environment. void SetEnvironment(Environment env); bool GetSkipPrologue() const; PathMappingList &GetSourcePathMap() const; bool GetAutoSourceMapRelative() const; FileSpecList GetExecutableSearchPaths(); void AppendExecutableSearchPaths(const FileSpec &); FileSpecList GetDebugFileSearchPaths(); FileSpecList GetClangModuleSearchPaths(); bool GetEnableAutoImportClangModules() const; ImportStdModule GetImportStdModule() const; DynamicClassInfoHelper GetDynamicClassInfoHelper() const; bool GetEnableAutoApplyFixIts() const; uint64_t GetNumberOfRetriesWithFixits() const; bool GetEnableNotifyAboutFixIts() const; FileSpec GetSaveJITObjectsDir() const; bool GetEnableSyntheticValue() const; bool ShowHexVariableValuesWithLeadingZeroes() const; uint32_t GetMaxZeroPaddingInFloatFormat() const; uint32_t GetMaximumNumberOfChildrenToDisplay() const; /// Get the max depth value, augmented with a bool to indicate whether the /// depth is the default. /// /// When the user has customized the max depth, the bool will be false. /// /// \returns the max depth, and true if the max depth is the system default, /// otherwise false. std::pair GetMaximumDepthOfChildrenToDisplay() const; uint32_t GetMaximumSizeOfStringSummary() const; uint32_t GetMaximumMemReadSize() const; FileSpec GetStandardInputPath() const; FileSpec GetStandardErrorPath() const; FileSpec GetStandardOutputPath() const; void SetStandardInputPath(llvm::StringRef path); void SetStandardOutputPath(llvm::StringRef path); void SetStandardErrorPath(llvm::StringRef path); void SetStandardInputPath(const char *path) = delete; void SetStandardOutputPath(const char *path) = delete; void SetStandardErrorPath(const char *path) = delete; bool GetBreakpointsConsultPlatformAvoidList(); lldb::LanguageType GetLanguage() const; llvm::StringRef GetExpressionPrefixContents(); uint64_t GetExprErrorLimit() const; uint64_t GetExprAllocAddress() const; uint64_t GetExprAllocSize() const; uint64_t GetExprAllocAlign() const; bool GetUseHexImmediates() const; bool GetUseFastStepping() const; bool GetDisplayExpressionsInCrashlogs() const; LoadScriptFromSymFile GetLoadScriptFromSymbolFile() const; LoadCWDlldbinitFile GetLoadCWDlldbinitFile() const; Disassembler::HexImmediateStyle GetHexImmediateStyle() const; MemoryModuleLoadLevel GetMemoryModuleLoadLevel() const; bool GetUserSpecifiedTrapHandlerNames(Args &args) const; void SetUserSpecifiedTrapHandlerNames(const Args &args); bool GetDisplayRuntimeSupportValues() const; void SetDisplayRuntimeSupportValues(bool b); bool GetDisplayRecognizedArguments() const; void SetDisplayRecognizedArguments(bool b); const ProcessLaunchInfo &GetProcessLaunchInfo() const; void SetProcessLaunchInfo(const ProcessLaunchInfo &launch_info); bool GetInjectLocalVariables(ExecutionContext *exe_ctx) const; void SetRequireHardwareBreakpoints(bool b); bool GetRequireHardwareBreakpoints() const; bool GetAutoInstallMainExecutable() const; void UpdateLaunchInfoFromProperties(); void SetDebugUtilityExpression(bool debug); bool GetDebugUtilityExpression() const; private: std::optional GetExperimentalPropertyValue(size_t prop_idx, ExecutionContext *exe_ctx = nullptr) const; // Callbacks for m_launch_info. void Arg0ValueChangedCallback(); void RunArgsValueChangedCallback(); void EnvVarsValueChangedCallback(); void InputPathValueChangedCallback(); void OutputPathValueChangedCallback(); void ErrorPathValueChangedCallback(); void DetachOnErrorValueChangedCallback(); void DisableASLRValueChangedCallback(); void InheritTCCValueChangedCallback(); void DisableSTDIOValueChangedCallback(); // Settings checker for target.jit-save-objects-dir: void CheckJITObjectsDir(); Environment ComputeEnvironment() const; // Member variables. ProcessLaunchInfo m_launch_info; std::unique_ptr m_experimental_properties_up; Target *m_target; }; class EvaluateExpressionOptions { public: // MSVC has a bug here that reports C4268: 'const' static/global data // initialized with compiler generated default constructor fills the object // with zeros. Confirmed that MSVC is *not* zero-initializing, it's just a // bogus warning. #if defined(_MSC_VER) #pragma warning(push) #pragma warning(disable : 4268) #endif static constexpr std::chrono::milliseconds default_timeout{500}; #if defined(_MSC_VER) #pragma warning(pop) #endif static constexpr ExecutionPolicy default_execution_policy = eExecutionPolicyOnlyWhenNeeded; EvaluateExpressionOptions() = default; ExecutionPolicy GetExecutionPolicy() const { return m_execution_policy; } void SetExecutionPolicy(ExecutionPolicy policy = eExecutionPolicyAlways) { m_execution_policy = policy; } lldb::LanguageType GetLanguage() const { return m_language; } void SetLanguage(lldb::LanguageType language) { m_language = language; } bool DoesCoerceToId() const { return m_coerce_to_id; } const char *GetPrefix() const { return (m_prefix.empty() ? nullptr : m_prefix.c_str()); } void SetPrefix(const char *prefix) { if (prefix && prefix[0]) m_prefix = prefix; else m_prefix.clear(); } void SetCoerceToId(bool coerce = true) { m_coerce_to_id = coerce; } bool DoesUnwindOnError() const { return m_unwind_on_error; } void SetUnwindOnError(bool unwind = false) { m_unwind_on_error = unwind; } bool DoesIgnoreBreakpoints() const { return m_ignore_breakpoints; } void SetIgnoreBreakpoints(bool ignore = false) { m_ignore_breakpoints = ignore; } bool DoesKeepInMemory() const { return m_keep_in_memory; } void SetKeepInMemory(bool keep = true) { m_keep_in_memory = keep; } lldb::DynamicValueType GetUseDynamic() const { return m_use_dynamic; } void SetUseDynamic(lldb::DynamicValueType dynamic = lldb::eDynamicCanRunTarget) { m_use_dynamic = dynamic; } const Timeout &GetTimeout() const { return m_timeout; } void SetTimeout(const Timeout &timeout) { m_timeout = timeout; } const Timeout &GetOneThreadTimeout() const { return m_one_thread_timeout; } void SetOneThreadTimeout(const Timeout &timeout) { m_one_thread_timeout = timeout; } bool GetTryAllThreads() const { return m_try_others; } void SetTryAllThreads(bool try_others = true) { m_try_others = try_others; } bool GetStopOthers() const { return m_stop_others; } void SetStopOthers(bool stop_others = true) { m_stop_others = stop_others; } bool GetDebug() const { return m_debug; } void SetDebug(bool b) { m_debug = b; if (m_debug) m_generate_debug_info = true; } bool GetGenerateDebugInfo() const { return m_generate_debug_info; } void SetGenerateDebugInfo(bool b) { m_generate_debug_info = b; } bool GetColorizeErrors() const { return m_ansi_color_errors; } void SetColorizeErrors(bool b) { m_ansi_color_errors = b; } bool GetTrapExceptions() const { return m_trap_exceptions; } void SetTrapExceptions(bool b) { m_trap_exceptions = b; } bool GetREPLEnabled() const { return m_repl; } void SetREPLEnabled(bool b) { m_repl = b; } void SetCancelCallback(lldb::ExpressionCancelCallback callback, void *baton) { m_cancel_callback_baton = baton; m_cancel_callback = callback; } bool InvokeCancelCallback(lldb::ExpressionEvaluationPhase phase) const { return ((m_cancel_callback != nullptr) ? m_cancel_callback(phase, m_cancel_callback_baton) : false); } // Allows the expression contents to be remapped to point to the specified // file and line using #line directives. void SetPoundLine(const char *path, uint32_t line) const { if (path && path[0]) { m_pound_line_file = path; m_pound_line_line = line; } else { m_pound_line_file.clear(); m_pound_line_line = 0; } } const char *GetPoundLineFilePath() const { return (m_pound_line_file.empty() ? nullptr : m_pound_line_file.c_str()); } uint32_t GetPoundLineLine() const { return m_pound_line_line; } void SetSuppressPersistentResult(bool b) { m_suppress_persistent_result = b; } bool GetSuppressPersistentResult() const { return m_suppress_persistent_result; } void SetAutoApplyFixIts(bool b) { m_auto_apply_fixits = b; } bool GetAutoApplyFixIts() const { return m_auto_apply_fixits; } void SetRetriesWithFixIts(uint64_t number_of_retries) { m_retries_with_fixits = number_of_retries; } uint64_t GetRetriesWithFixIts() const { return m_retries_with_fixits; } bool IsForUtilityExpr() const { return m_running_utility_expression; } void SetIsForUtilityExpr(bool b) { m_running_utility_expression = b; } private: ExecutionPolicy m_execution_policy = default_execution_policy; lldb::LanguageType m_language = lldb::eLanguageTypeUnknown; std::string m_prefix; bool m_coerce_to_id = false; bool m_unwind_on_error = true; bool m_ignore_breakpoints = false; bool m_keep_in_memory = false; bool m_try_others = true; bool m_stop_others = true; bool m_debug = false; bool m_trap_exceptions = true; bool m_repl = false; bool m_generate_debug_info = false; bool m_ansi_color_errors = false; bool m_suppress_persistent_result = false; bool m_auto_apply_fixits = true; uint64_t m_retries_with_fixits = 1; /// True if the executed code should be treated as utility code that is only /// used by LLDB internally. bool m_running_utility_expression = false; lldb::DynamicValueType m_use_dynamic = lldb::eNoDynamicValues; Timeout m_timeout = default_timeout; Timeout m_one_thread_timeout = std::nullopt; lldb::ExpressionCancelCallback m_cancel_callback = nullptr; void *m_cancel_callback_baton = nullptr; // If m_pound_line_file is not empty and m_pound_line_line is non-zero, use // #line %u "%s" before the expression content to remap where the source // originates mutable std::string m_pound_line_file; mutable uint32_t m_pound_line_line = 0; }; // Target class Target : public std::enable_shared_from_this, public TargetProperties, public Broadcaster, public ExecutionContextScope, public ModuleList::Notifier { public: friend class TargetList; friend class Debugger; /// Broadcaster event bits definitions. enum { eBroadcastBitBreakpointChanged = (1 << 0), eBroadcastBitModulesLoaded = (1 << 1), eBroadcastBitModulesUnloaded = (1 << 2), eBroadcastBitWatchpointChanged = (1 << 3), eBroadcastBitSymbolsLoaded = (1 << 4), eBroadcastBitSymbolsChanged = (1 << 5), }; // These two functions fill out the Broadcaster interface: static ConstString &GetStaticBroadcasterClass(); ConstString &GetBroadcasterClass() const override { return GetStaticBroadcasterClass(); } // This event data class is for use by the TargetList to broadcast new target // notifications. class TargetEventData : public EventData { public: TargetEventData(const lldb::TargetSP &target_sp); TargetEventData(const lldb::TargetSP &target_sp, const ModuleList &module_list); ~TargetEventData() override; static llvm::StringRef GetFlavorString(); llvm::StringRef GetFlavor() const override { return TargetEventData::GetFlavorString(); } void Dump(Stream *s) const override; static const TargetEventData *GetEventDataFromEvent(const Event *event_ptr); static lldb::TargetSP GetTargetFromEvent(const Event *event_ptr); static ModuleList GetModuleListFromEvent(const Event *event_ptr); const lldb::TargetSP &GetTarget() const { return m_target_sp; } const ModuleList &GetModuleList() const { return m_module_list; } private: lldb::TargetSP m_target_sp; ModuleList m_module_list; TargetEventData(const TargetEventData &) = delete; const TargetEventData &operator=(const TargetEventData &) = delete; }; ~Target() override; static void SettingsInitialize(); static void SettingsTerminate(); static FileSpecList GetDefaultExecutableSearchPaths(); static FileSpecList GetDefaultDebugFileSearchPaths(); static ArchSpec GetDefaultArchitecture(); static void SetDefaultArchitecture(const ArchSpec &arch); bool IsDummyTarget() const { return m_is_dummy_target; } const std::string &GetLabel() const { return m_label; } /// Set a label for a target. /// /// The label cannot be used by another target or be only integral. /// /// \return /// The label for this target or an error if the label didn't match the /// requirements. llvm::Error SetLabel(llvm::StringRef label); /// Find a binary on the system and return its Module, /// or return an existing Module that is already in the Target. /// /// Given a ModuleSpec, find a binary satisifying that specification, /// or identify a matching Module already present in the Target, /// and return a shared pointer to it. /// /// \param[in] module_spec /// The criteria that must be matched for the binary being loaded. /// e.g. UUID, architecture, file path. /// /// \param[in] notify /// If notify is true, and the Module is new to this Target, /// Target::ModulesDidLoad will be called. /// If notify is false, it is assumed that the caller is adding /// multiple Modules and will call ModulesDidLoad with the /// full list at the end. /// ModulesDidLoad must be called when a Module/Modules have /// been added to the target, one way or the other. /// /// \param[out] error_ptr /// Optional argument, pointing to a Status object to fill in /// with any results / messages while attempting to find/load /// this binary. Many callers will be internal functions that /// will handle / summarize the failures in a custom way and /// don't use these messages. /// /// \return /// An empty ModuleSP will be returned if no matching file /// was found. If error_ptr was non-nullptr, an error message /// will likely be provided. lldb::ModuleSP GetOrCreateModule(const ModuleSpec &module_spec, bool notify, Status *error_ptr = nullptr); // Settings accessors static TargetProperties &GetGlobalProperties(); std::recursive_mutex &GetAPIMutex(); void DeleteCurrentProcess(); void CleanupProcess(); /// Dump a description of this object to a Stream. /// /// Dump a description of the contents of this object to the /// supplied stream \a s. The dumped content will be only what has /// been loaded or parsed up to this point at which this function /// is called, so this is a good way to see what has been parsed /// in a target. /// /// \param[in] s /// The stream to which to dump the object description. void Dump(Stream *s, lldb::DescriptionLevel description_level); // If listener_sp is null, the listener of the owning Debugger object will be // used. const lldb::ProcessSP &CreateProcess(lldb::ListenerSP listener_sp, llvm::StringRef plugin_name, const FileSpec *crash_file, bool can_connect); const lldb::ProcessSP &GetProcessSP() const; bool IsValid() { return m_valid; } void Destroy(); Status Launch(ProcessLaunchInfo &launch_info, Stream *stream); // Optional stream to receive first stop info Status Attach(ProcessAttachInfo &attach_info, Stream *stream); // Optional stream to receive first stop info // This part handles the breakpoints. BreakpointList &GetBreakpointList(bool internal = false); const BreakpointList &GetBreakpointList(bool internal = false) const; lldb::BreakpointSP GetLastCreatedBreakpoint() { return m_last_created_breakpoint; } lldb::BreakpointSP GetBreakpointByID(lldb::break_id_t break_id); lldb::BreakpointSP CreateBreakpointAtUserEntry(Status &error); // Use this to create a file and line breakpoint to a given module or all // module it is nullptr lldb::BreakpointSP CreateBreakpoint(const FileSpecList *containingModules, const FileSpec &file, uint32_t line_no, uint32_t column, lldb::addr_t offset, LazyBool check_inlines, LazyBool skip_prologue, bool internal, bool request_hardware, LazyBool move_to_nearest_code); // Use this to create breakpoint that matches regex against the source lines // in files given in source_file_list: If function_names is non-empty, also // filter by function after the matches are made. lldb::BreakpointSP CreateSourceRegexBreakpoint( const FileSpecList *containingModules, const FileSpecList *source_file_list, const std::unordered_set &function_names, RegularExpression source_regex, bool internal, bool request_hardware, LazyBool move_to_nearest_code); // Use this to create a breakpoint from a load address lldb::BreakpointSP CreateBreakpoint(lldb::addr_t load_addr, bool internal, bool request_hardware); // Use this to create a breakpoint from a load address and a module file spec lldb::BreakpointSP CreateAddressInModuleBreakpoint(lldb::addr_t file_addr, bool internal, const FileSpec &file_spec, bool request_hardware); // Use this to create Address breakpoints: lldb::BreakpointSP CreateBreakpoint(const Address &addr, bool internal, bool request_hardware); // Use this to create a function breakpoint by regexp in // containingModule/containingSourceFiles, or all modules if it is nullptr // When "skip_prologue is set to eLazyBoolCalculate, we use the current // target setting, else we use the values passed in lldb::BreakpointSP CreateFuncRegexBreakpoint( const FileSpecList *containingModules, const FileSpecList *containingSourceFiles, RegularExpression func_regexp, lldb::LanguageType requested_language, LazyBool skip_prologue, bool internal, bool request_hardware); // Use this to create a function breakpoint by name in containingModule, or // all modules if it is nullptr When "skip_prologue is set to // eLazyBoolCalculate, we use the current target setting, else we use the // values passed in. func_name_type_mask is or'ed values from the // FunctionNameType enum. lldb::BreakpointSP CreateBreakpoint( const FileSpecList *containingModules, const FileSpecList *containingSourceFiles, const char *func_name, lldb::FunctionNameType func_name_type_mask, lldb::LanguageType language, lldb::addr_t offset, LazyBool skip_prologue, bool internal, bool request_hardware); lldb::BreakpointSP CreateExceptionBreakpoint(enum lldb::LanguageType language, bool catch_bp, bool throw_bp, bool internal, Args *additional_args = nullptr, Status *additional_args_error = nullptr); lldb::BreakpointSP CreateScriptedBreakpoint( const llvm::StringRef class_name, const FileSpecList *containingModules, const FileSpecList *containingSourceFiles, bool internal, bool request_hardware, StructuredData::ObjectSP extra_args_sp, Status *creation_error = nullptr); // This is the same as the func_name breakpoint except that you can specify a // vector of names. This is cheaper than a regular expression breakpoint in // the case where you just want to set a breakpoint on a set of names you // already know. func_name_type_mask is or'ed values from the // FunctionNameType enum. lldb::BreakpointSP CreateBreakpoint( const FileSpecList *containingModules, const FileSpecList *containingSourceFiles, const char *func_names[], size_t num_names, lldb::FunctionNameType func_name_type_mask, lldb::LanguageType language, lldb::addr_t offset, LazyBool skip_prologue, bool internal, bool request_hardware); lldb::BreakpointSP CreateBreakpoint(const FileSpecList *containingModules, const FileSpecList *containingSourceFiles, const std::vector &func_names, lldb::FunctionNameType func_name_type_mask, lldb::LanguageType language, lldb::addr_t m_offset, LazyBool skip_prologue, bool internal, bool request_hardware); // Use this to create a general breakpoint: lldb::BreakpointSP CreateBreakpoint(lldb::SearchFilterSP &filter_sp, lldb::BreakpointResolverSP &resolver_sp, bool internal, bool request_hardware, bool resolve_indirect_symbols); // Use this to create a watchpoint: lldb::WatchpointSP CreateWatchpoint(lldb::addr_t addr, size_t size, const CompilerType *type, uint32_t kind, Status &error); lldb::WatchpointSP GetLastCreatedWatchpoint() { return m_last_created_watchpoint; } WatchpointList &GetWatchpointList() { return m_watchpoint_list; } // Manages breakpoint names: void AddNameToBreakpoint(BreakpointID &id, llvm::StringRef name, Status &error); void AddNameToBreakpoint(lldb::BreakpointSP &bp_sp, llvm::StringRef name, Status &error); void RemoveNameFromBreakpoint(lldb::BreakpointSP &bp_sp, ConstString name); BreakpointName *FindBreakpointName(ConstString name, bool can_create, Status &error); void DeleteBreakpointName(ConstString name); void ConfigureBreakpointName(BreakpointName &bp_name, const BreakpointOptions &options, const BreakpointName::Permissions &permissions); void ApplyNameToBreakpoints(BreakpointName &bp_name); void AddBreakpointName(std::unique_ptr bp_name); void GetBreakpointNames(std::vector &names); // This call removes ALL breakpoints regardless of permission. void RemoveAllBreakpoints(bool internal_also = false); // This removes all the breakpoints, but obeys the ePermDelete on them. void RemoveAllowedBreakpoints(); void DisableAllBreakpoints(bool internal_also = false); void DisableAllowedBreakpoints(); void EnableAllBreakpoints(bool internal_also = false); void EnableAllowedBreakpoints(); bool DisableBreakpointByID(lldb::break_id_t break_id); bool EnableBreakpointByID(lldb::break_id_t break_id); bool RemoveBreakpointByID(lldb::break_id_t break_id); /// Resets the hit count of all breakpoints. void ResetBreakpointHitCounts(); // The flag 'end_to_end', default to true, signifies that the operation is // performed end to end, for both the debugger and the debuggee. bool RemoveAllWatchpoints(bool end_to_end = true); bool DisableAllWatchpoints(bool end_to_end = true); bool EnableAllWatchpoints(bool end_to_end = true); bool ClearAllWatchpointHitCounts(); bool ClearAllWatchpointHistoricValues(); bool IgnoreAllWatchpoints(uint32_t ignore_count); bool DisableWatchpointByID(lldb::watch_id_t watch_id); bool EnableWatchpointByID(lldb::watch_id_t watch_id); bool RemoveWatchpointByID(lldb::watch_id_t watch_id); bool IgnoreWatchpointByID(lldb::watch_id_t watch_id, uint32_t ignore_count); Status SerializeBreakpointsToFile(const FileSpec &file, const BreakpointIDList &bp_ids, bool append); Status CreateBreakpointsFromFile(const FileSpec &file, BreakpointIDList &new_bps); Status CreateBreakpointsFromFile(const FileSpec &file, std::vector &names, BreakpointIDList &new_bps); /// Get \a load_addr as a callable code load address for this target /// /// Take \a load_addr and potentially add any address bits that are /// needed to make the address callable. For ARM this can set bit /// zero (if it already isn't) if \a load_addr is a thumb function. /// If \a addr_class is set to AddressClass::eInvalid, then the address /// adjustment will always happen. If it is set to an address class /// that doesn't have code in it, LLDB_INVALID_ADDRESS will be /// returned. lldb::addr_t GetCallableLoadAddress( lldb::addr_t load_addr, AddressClass addr_class = AddressClass::eInvalid) const; /// Get \a load_addr as an opcode for this target. /// /// Take \a load_addr and potentially strip any address bits that are /// needed to make the address point to an opcode. For ARM this can /// clear bit zero (if it already isn't) if \a load_addr is a /// thumb function and load_addr is in code. /// If \a addr_class is set to AddressClass::eInvalid, then the address /// adjustment will always happen. If it is set to an address class /// that doesn't have code in it, LLDB_INVALID_ADDRESS will be /// returned. lldb::addr_t GetOpcodeLoadAddress(lldb::addr_t load_addr, AddressClass addr_class = AddressClass::eInvalid) const; // Get load_addr as breakable load address for this target. Take a addr and // check if for any reason there is a better address than this to put a // breakpoint on. If there is then return that address. For MIPS, if // instruction at addr is a delay slot instruction then this method will find // the address of its previous instruction and return that address. lldb::addr_t GetBreakableLoadAddress(lldb::addr_t addr); void ModulesDidLoad(ModuleList &module_list); void ModulesDidUnload(ModuleList &module_list, bool delete_locations); void SymbolsDidLoad(ModuleList &module_list); void ClearModules(bool delete_locations); /// Called as the last function in Process::DidExec(). /// /// Process::DidExec() will clear a lot of state in the process, /// then try to reload a dynamic loader plugin to discover what /// binaries are currently available and then this function should /// be called to allow the target to do any cleanup after everything /// has been figured out. It can remove breakpoints that no longer /// make sense as the exec might have changed the target /// architecture, and unloaded some modules that might get deleted. void DidExec(); /// Gets the module for the main executable. /// /// Each process has a notion of a main executable that is the file /// that will be executed or attached to. Executable files can have /// dependent modules that are discovered from the object files, or /// discovered at runtime as things are dynamically loaded. /// /// \return /// The shared pointer to the executable module which can /// contains a nullptr Module object if no executable has been /// set. /// /// \see DynamicLoader /// \see ObjectFile::GetDependentModules (FileSpecList&) /// \see Process::SetExecutableModule(lldb::ModuleSP&) lldb::ModuleSP GetExecutableModule(); Module *GetExecutableModulePointer(); /// Set the main executable module. /// /// Each process has a notion of a main executable that is the file /// that will be executed or attached to. Executable files can have /// dependent modules that are discovered from the object files, or /// discovered at runtime as things are dynamically loaded. /// /// Setting the executable causes any of the current dependent /// image information to be cleared and replaced with the static /// dependent image information found by calling /// ObjectFile::GetDependentModules (FileSpecList&) on the main /// executable and any modules on which it depends. Calling /// Process::GetImages() will return the newly found images that /// were obtained from all of the object files. /// /// \param[in] module_sp /// A shared pointer reference to the module that will become /// the main executable for this process. /// /// \param[in] load_dependent_files /// If \b true then ask the object files to track down any /// known dependent files. /// /// \see ObjectFile::GetDependentModules (FileSpecList&) /// \see Process::GetImages() void SetExecutableModule( lldb::ModuleSP &module_sp, LoadDependentFiles load_dependent_files = eLoadDependentsDefault); bool LoadScriptingResources(std::list &errors, Stream &feedback_stream, bool continue_on_error = true) { return m_images.LoadScriptingResourcesInTarget( this, errors, feedback_stream, continue_on_error); } /// Get accessor for the images for this process. /// /// Each process has a notion of a main executable that is the file /// that will be executed or attached to. Executable files can have /// dependent modules that are discovered from the object files, or /// discovered at runtime as things are dynamically loaded. After /// a main executable has been set, the images will contain a list /// of all the files that the executable depends upon as far as the /// object files know. These images will usually contain valid file /// virtual addresses only. When the process is launched or attached /// to, the DynamicLoader plug-in will discover where these images /// were loaded in memory and will resolve the load virtual /// addresses is each image, and also in images that are loaded by /// code. /// /// \return /// A list of Module objects in a module list. const ModuleList &GetImages() const { return m_images; } ModuleList &GetImages() { return m_images; } /// Return whether this FileSpec corresponds to a module that should be /// considered for general searches. /// /// This API will be consulted by the SearchFilterForUnconstrainedSearches /// and any module that returns \b true will not be searched. Note the /// SearchFilterForUnconstrainedSearches is the search filter that /// gets used in the CreateBreakpoint calls when no modules is provided. /// /// The target call at present just consults the Platform's call of the /// same name. /// /// \param[in] module_spec /// Path to the module. /// /// \return \b true if the module should be excluded, \b false otherwise. bool ModuleIsExcludedForUnconstrainedSearches(const FileSpec &module_spec); /// Return whether this module should be considered for general searches. /// /// This API will be consulted by the SearchFilterForUnconstrainedSearches /// and any module that returns \b true will not be searched. Note the /// SearchFilterForUnconstrainedSearches is the search filter that /// gets used in the CreateBreakpoint calls when no modules is provided. /// /// The target call at present just consults the Platform's call of the /// same name. /// /// FIXME: When we get time we should add a way for the user to set modules /// that they /// don't want searched, in addition to or instead of the platform ones. /// /// \param[in] module_sp /// A shared pointer reference to the module that checked. /// /// \return \b true if the module should be excluded, \b false otherwise. bool ModuleIsExcludedForUnconstrainedSearches(const lldb::ModuleSP &module_sp); const ArchSpec &GetArchitecture() const { return m_arch.GetSpec(); } /// Returns the name of the target's ABI plugin. llvm::StringRef GetABIName() const; /// Set the architecture for this target. /// /// If the current target has no Images read in, then this just sets the /// architecture, which will be used to select the architecture of the /// ExecutableModule when that is set. If the current target has an /// ExecutableModule, then calling SetArchitecture with a different /// architecture from the currently selected one will reset the /// ExecutableModule to that slice of the file backing the ExecutableModule. /// If the file backing the ExecutableModule does not contain a fork of this /// architecture, then this code will return false, and the architecture /// won't be changed. If the input arch_spec is the same as the already set /// architecture, this is a no-op. /// /// \param[in] arch_spec /// The new architecture. /// /// \param[in] set_platform /// If \b true, then the platform will be adjusted if the currently /// selected platform is not compatible with the architecture being set. /// If \b false, then just the architecture will be set even if the /// currently selected platform isn't compatible (in case it might be /// manually set following this function call). /// /// \param[in] merged /// If true, arch_spec is merged with the current /// architecture. Otherwise it's replaced. /// /// \return /// \b true if the architecture was successfully set, \b false otherwise. bool SetArchitecture(const ArchSpec &arch_spec, bool set_platform = false, bool merge = true); bool MergeArchitecture(const ArchSpec &arch_spec); Architecture *GetArchitecturePlugin() const { return m_arch.GetPlugin(); } Debugger &GetDebugger() { return m_debugger; } size_t ReadMemoryFromFileCache(const Address &addr, void *dst, size_t dst_len, Status &error); // Reading memory through the target allows us to skip going to the process // for reading memory if possible and it allows us to try and read from any // constant sections in our object files on disk. If you always want live // program memory, read straight from the process. If you possibly want to // read from const sections in object files, read from the target. This // version of ReadMemory will try and read memory from the process if the // process is alive. The order is: // 1 - if (force_live_memory == false) and the address falls in a read-only // section, then read from the file cache // 2 - if there is a process, then read from memory // 3 - if there is no process, then read from the file cache size_t ReadMemory(const Address &addr, void *dst, size_t dst_len, Status &error, bool force_live_memory = false, lldb::addr_t *load_addr_ptr = nullptr); size_t ReadCStringFromMemory(const Address &addr, std::string &out_str, Status &error, bool force_live_memory = false); size_t ReadCStringFromMemory(const Address &addr, char *dst, size_t dst_max_len, Status &result_error, bool force_live_memory = false); /// Read a NULL terminated string from memory /// /// This function will read a cache page at a time until a NULL string /// terminator is found. It will stop reading if an aligned sequence of NULL /// termination \a type_width bytes is not found before reading \a /// cstr_max_len bytes. The results are always guaranteed to be NULL /// terminated, and that no more than (max_bytes - type_width) bytes will be /// read. /// /// \param[in] addr /// The address to start the memory read. /// /// \param[in] dst /// A character buffer containing at least max_bytes. /// /// \param[in] max_bytes /// The maximum number of bytes to read. /// /// \param[in] error /// The error status of the read operation. /// /// \param[in] type_width /// The size of the null terminator (1 to 4 bytes per /// character). Defaults to 1. /// /// \return /// The error status or the number of bytes prior to the null terminator. size_t ReadStringFromMemory(const Address &addr, char *dst, size_t max_bytes, Status &error, size_t type_width, bool force_live_memory = true); size_t ReadScalarIntegerFromMemory(const Address &addr, uint32_t byte_size, bool is_signed, Scalar &scalar, Status &error, bool force_live_memory = false); uint64_t ReadUnsignedIntegerFromMemory(const Address &addr, size_t integer_byte_size, uint64_t fail_value, Status &error, bool force_live_memory = false); bool ReadPointerFromMemory(const Address &addr, Status &error, Address &pointer_addr, bool force_live_memory = false); SectionLoadList &GetSectionLoadList() { return m_section_load_history.GetCurrentSectionLoadList(); } static Target *GetTargetFromContexts(const ExecutionContext *exe_ctx_ptr, const SymbolContext *sc_ptr); // lldb::ExecutionContextScope pure virtual functions lldb::TargetSP CalculateTarget() override; lldb::ProcessSP CalculateProcess() override; lldb::ThreadSP CalculateThread() override; lldb::StackFrameSP CalculateStackFrame() override; void CalculateExecutionContext(ExecutionContext &exe_ctx) override; PathMappingList &GetImageSearchPathList(); llvm::Expected GetScratchTypeSystemForLanguage(lldb::LanguageType language, bool create_on_demand = true); std::vector GetScratchTypeSystems(bool create_on_demand = true); PersistentExpressionState * GetPersistentExpressionStateForLanguage(lldb::LanguageType language); // Creates a UserExpression for the given language, the rest of the // parameters have the same meaning as for the UserExpression constructor. // Returns a new-ed object which the caller owns. UserExpression * GetUserExpressionForLanguage(llvm::StringRef expr, llvm::StringRef prefix, lldb::LanguageType language, Expression::ResultType desired_type, const EvaluateExpressionOptions &options, ValueObject *ctx_obj, Status &error); // Creates a FunctionCaller for the given language, the rest of the // parameters have the same meaning as for the FunctionCaller constructor. // Since a FunctionCaller can't be // IR Interpreted, it makes no sense to call this with an // ExecutionContextScope that lacks // a Process. // Returns a new-ed object which the caller owns. FunctionCaller *GetFunctionCallerForLanguage(lldb::LanguageType language, const CompilerType &return_type, const Address &function_address, const ValueList &arg_value_list, const char *name, Status &error); /// Creates and installs a UtilityFunction for the given language. llvm::Expected> CreateUtilityFunction(std::string expression, std::string name, lldb::LanguageType language, ExecutionContext &exe_ctx); // Install any files through the platform that need be to installed prior to // launching or attaching. Status Install(ProcessLaunchInfo *launch_info); bool ResolveFileAddress(lldb::addr_t load_addr, Address &so_addr); bool ResolveLoadAddress(lldb::addr_t load_addr, Address &so_addr, uint32_t stop_id = SectionLoadHistory::eStopIDNow); bool SetSectionLoadAddress(const lldb::SectionSP §ion, lldb::addr_t load_addr, bool warn_multiple = false); size_t UnloadModuleSections(const lldb::ModuleSP &module_sp); size_t UnloadModuleSections(const ModuleList &module_list); bool SetSectionUnloaded(const lldb::SectionSP §ion_sp); bool SetSectionUnloaded(const lldb::SectionSP §ion_sp, lldb::addr_t load_addr); void ClearAllLoadedSections(); /// Set the \a Trace object containing processor trace information of this /// target. /// /// \param[in] trace_sp /// The trace object. void SetTrace(const lldb::TraceSP &trace_sp); /// Get the \a Trace object containing processor trace information of this /// target. /// /// \return /// The trace object. It might be undefined. lldb::TraceSP GetTrace(); /// Create a \a Trace object for the current target using the using the /// default supported tracing technology for this process. /// /// \return /// The new \a Trace or an \a llvm::Error if a \a Trace already exists or /// the trace couldn't be created. llvm::Expected CreateTrace(); /// If a \a Trace object is present, this returns it, otherwise a new Trace is /// created with \a Trace::CreateTrace. llvm::Expected GetTraceOrCreate(); // Since expressions results can persist beyond the lifetime of a process, // and the const expression results are available after a process is gone, we // provide a way for expressions to be evaluated from the Target itself. If // an expression is going to be run, then it should have a frame filled in in // the execution context. lldb::ExpressionResults EvaluateExpression( llvm::StringRef expression, ExecutionContextScope *exe_scope, lldb::ValueObjectSP &result_valobj_sp, const EvaluateExpressionOptions &options = EvaluateExpressionOptions(), std::string *fixed_expression = nullptr, ValueObject *ctx_obj = nullptr); lldb::ExpressionVariableSP GetPersistentVariable(ConstString name); lldb::addr_t GetPersistentSymbol(ConstString name); /// This method will return the address of the starting function for /// this binary, e.g. main() or its equivalent. This can be used as /// an address of a function that is not called once a binary has /// started running - e.g. as a return address for inferior function /// calls that are unambiguous completion of the function call, not /// called during the course of the inferior function code running. /// /// If no entry point can be found, an invalid address is returned. /// /// \param [out] err /// This object will be set to failure if no entry address could /// be found, and may contain a helpful error message. // /// \return /// Returns the entry address for this program, or an error /// if none can be found. llvm::Expected GetEntryPointAddress(); CompilerType GetRegisterType(const std::string &name, const lldb_private::RegisterFlags &flags, uint32_t byte_size); // Target Stop Hooks class StopHook : public UserID { public: StopHook(const StopHook &rhs); virtual ~StopHook() = default; enum class StopHookKind : uint32_t { CommandBased = 0, ScriptBased }; enum class StopHookResult : uint32_t { KeepStopped = 0, RequestContinue, AlreadyContinued }; lldb::TargetSP &GetTarget() { return m_target_sp; } // Set the specifier. The stop hook will own the specifier, and is // responsible for deleting it when we're done. void SetSpecifier(SymbolContextSpecifier *specifier); SymbolContextSpecifier *GetSpecifier() { return m_specifier_sp.get(); } bool ExecutionContextPasses(const ExecutionContext &exe_ctx); // Called on stop, this gets passed the ExecutionContext for each "stop // with a reason" thread. It should add to the stream whatever text it // wants to show the user, and return False to indicate it wants the target // not to stop. virtual StopHookResult HandleStop(ExecutionContext &exe_ctx, lldb::StreamSP output) = 0; // Set the Thread Specifier. The stop hook will own the thread specifier, // and is responsible for deleting it when we're done. void SetThreadSpecifier(ThreadSpec *specifier); ThreadSpec *GetThreadSpecifier() { return m_thread_spec_up.get(); } bool IsActive() { return m_active; } void SetIsActive(bool is_active) { m_active = is_active; } void SetAutoContinue(bool auto_continue) { m_auto_continue = auto_continue; } bool GetAutoContinue() const { return m_auto_continue; } void GetDescription(Stream &s, lldb::DescriptionLevel level) const; virtual void GetSubclassDescription(Stream &s, lldb::DescriptionLevel level) const = 0; protected: lldb::TargetSP m_target_sp; lldb::SymbolContextSpecifierSP m_specifier_sp; std::unique_ptr m_thread_spec_up; bool m_active = true; bool m_auto_continue = false; StopHook(lldb::TargetSP target_sp, lldb::user_id_t uid); }; class StopHookCommandLine : public StopHook { public: ~StopHookCommandLine() override = default; StringList &GetCommands() { return m_commands; } void SetActionFromString(const std::string &strings); void SetActionFromStrings(const std::vector &strings); StopHookResult HandleStop(ExecutionContext &exc_ctx, lldb::StreamSP output_sp) override; void GetSubclassDescription(Stream &s, lldb::DescriptionLevel level) const override; private: StringList m_commands; // Use CreateStopHook to make a new empty stop hook. The GetCommandPointer // and fill it with commands, and SetSpecifier to set the specifier shared // pointer (can be null, that will match anything.) StopHookCommandLine(lldb::TargetSP target_sp, lldb::user_id_t uid) : StopHook(target_sp, uid) {} friend class Target; }; class StopHookScripted : public StopHook { public: ~StopHookScripted() override = default; StopHookResult HandleStop(ExecutionContext &exc_ctx, lldb::StreamSP output) override; Status SetScriptCallback(std::string class_name, StructuredData::ObjectSP extra_args_sp); void GetSubclassDescription(Stream &s, lldb::DescriptionLevel level) const override; private: std::string m_class_name; /// This holds the dictionary of keys & values that can be used to /// parametrize any given callback's behavior. StructuredDataImpl m_extra_args; /// This holds the python callback object. StructuredData::GenericSP m_implementation_sp; /// Use CreateStopHook to make a new empty stop hook. The GetCommandPointer /// and fill it with commands, and SetSpecifier to set the specifier shared /// pointer (can be null, that will match anything.) StopHookScripted(lldb::TargetSP target_sp, lldb::user_id_t uid) : StopHook(target_sp, uid) {} friend class Target; }; typedef std::shared_ptr StopHookSP; /// Add an empty stop hook to the Target's stop hook list, and returns a /// shared pointer to it in new_hook. Returns the id of the new hook. StopHookSP CreateStopHook(StopHook::StopHookKind kind); /// If you tried to create a stop hook, and that failed, call this to /// remove the stop hook, as it will also reset the stop hook counter. void UndoCreateStopHook(lldb::user_id_t uid); // Runs the stop hooks that have been registered for this target. // Returns true if the stop hooks cause the target to resume. bool RunStopHooks(); size_t GetStopHookSize(); bool SetSuppresStopHooks(bool suppress) { bool old_value = m_suppress_stop_hooks; m_suppress_stop_hooks = suppress; return old_value; } bool GetSuppressStopHooks() { return m_suppress_stop_hooks; } bool RemoveStopHookByID(lldb::user_id_t uid); void RemoveAllStopHooks(); StopHookSP GetStopHookByID(lldb::user_id_t uid); bool SetStopHookActiveStateByID(lldb::user_id_t uid, bool active_state); void SetAllStopHooksActiveState(bool active_state); size_t GetNumStopHooks() const { return m_stop_hooks.size(); } StopHookSP GetStopHookAtIndex(size_t index) { if (index >= GetNumStopHooks()) return StopHookSP(); StopHookCollection::iterator pos = m_stop_hooks.begin(); while (index > 0) { pos++; index--; } return (*pos).second; } lldb::PlatformSP GetPlatform() { return m_platform_sp; } void SetPlatform(const lldb::PlatformSP &platform_sp) { m_platform_sp = platform_sp; } SourceManager &GetSourceManager(); // Methods. lldb::SearchFilterSP GetSearchFilterForModule(const FileSpec *containingModule); lldb::SearchFilterSP GetSearchFilterForModuleList(const FileSpecList *containingModuleList); lldb::SearchFilterSP GetSearchFilterForModuleAndCUList(const FileSpecList *containingModules, const FileSpecList *containingSourceFiles); lldb::REPLSP GetREPL(Status &err, lldb::LanguageType language, const char *repl_options, bool can_create); void SetREPL(lldb::LanguageType language, lldb::REPLSP repl_sp); StackFrameRecognizerManager &GetFrameRecognizerManager() { return *m_frame_recognizer_manager_up; } void SaveScriptedLaunchInfo(lldb_private::ProcessInfo &process_info); /// Add a signal for the target. This will get copied over to the process /// if the signal exists on that target. Only the values with Yes and No are /// set, Calculate values will be ignored. protected: struct DummySignalValues { LazyBool pass = eLazyBoolCalculate; LazyBool notify = eLazyBoolCalculate; LazyBool stop = eLazyBoolCalculate; DummySignalValues(LazyBool pass, LazyBool notify, LazyBool stop) : pass(pass), notify(notify), stop(stop) {} DummySignalValues() = default; }; using DummySignalElement = llvm::StringMapEntry; static bool UpdateSignalFromDummy(lldb::UnixSignalsSP signals_sp, const DummySignalElement &element); static bool ResetSignalFromDummy(lldb::UnixSignalsSP signals_sp, const DummySignalElement &element); public: /// Add a signal to the Target's list of stored signals/actions. These /// values will get copied into any processes launched from /// this target. void AddDummySignal(llvm::StringRef name, LazyBool pass, LazyBool print, LazyBool stop); /// Updates the signals in signals_sp using the stored dummy signals. /// If warning_stream_sp is not null, if any stored signals are not found in /// the current process, a warning will be emitted here. void UpdateSignalsFromDummy(lldb::UnixSignalsSP signals_sp, lldb::StreamSP warning_stream_sp); /// Clear the dummy signals in signal_names from the target, or all signals /// if signal_names is empty. Also remove the behaviors they set from the /// process's signals if it exists. void ClearDummySignals(Args &signal_names); /// Print all the signals set in this target. void PrintDummySignals(Stream &strm, Args &signals); protected: /// Implementing of ModuleList::Notifier. void NotifyModuleAdded(const ModuleList &module_list, const lldb::ModuleSP &module_sp) override; void NotifyModuleRemoved(const ModuleList &module_list, const lldb::ModuleSP &module_sp) override; void NotifyModuleUpdated(const ModuleList &module_list, const lldb::ModuleSP &old_module_sp, const lldb::ModuleSP &new_module_sp) override; void NotifyWillClearList(const ModuleList &module_list) override; void NotifyModulesRemoved(lldb_private::ModuleList &module_list) override; class Arch { public: explicit Arch(const ArchSpec &spec); const Arch &operator=(const ArchSpec &spec); const ArchSpec &GetSpec() const { return m_spec; } Architecture *GetPlugin() const { return m_plugin_up.get(); } private: ArchSpec m_spec; std::unique_ptr m_plugin_up; }; // Member variables. Debugger &m_debugger; lldb::PlatformSP m_platform_sp; ///< The platform for this target. std::recursive_mutex m_mutex; ///< An API mutex that is used by the lldb::SB* /// classes make the SB interface thread safe /// When the private state thread calls SB API's - usually because it is /// running OS plugin or Python ThreadPlan code - it should not block on the /// API mutex that is held by the code that kicked off the sequence of events /// that led us to run the code. We hand out this mutex instead when we /// detect that code is running on the private state thread. std::recursive_mutex m_private_mutex; Arch m_arch; std::string m_label; ModuleList m_images; ///< The list of images for this process (shared /// libraries and anything dynamically loaded). SectionLoadHistory m_section_load_history; BreakpointList m_breakpoint_list; BreakpointList m_internal_breakpoint_list; using BreakpointNameList = std::map>; BreakpointNameList m_breakpoint_names; lldb::BreakpointSP m_last_created_breakpoint; WatchpointList m_watchpoint_list; lldb::WatchpointSP m_last_created_watchpoint; // We want to tightly control the process destruction process so we can // correctly tear down everything that we need to, so the only class that // knows about the process lifespan is this target class. lldb::ProcessSP m_process_sp; lldb::SearchFilterSP m_search_filter_sp; PathMappingList m_image_search_paths; TypeSystemMap m_scratch_type_system_map; typedef std::map REPLMap; REPLMap m_repl_map; lldb::SourceManagerUP m_source_manager_up; typedef std::map StopHookCollection; StopHookCollection m_stop_hooks; lldb::user_id_t m_stop_hook_next_id; uint32_t m_latest_stop_hook_id; /// This records the last natural stop at /// which we ran a stop-hook. bool m_valid; bool m_suppress_stop_hooks; /// Used to not run stop hooks for expressions bool m_is_dummy_target; unsigned m_next_persistent_variable_index = 0; /// An optional \a lldb_private::Trace object containing processor trace /// information of this target. lldb::TraceSP m_trace_sp; /// Stores the frame recognizers of this target. lldb::StackFrameRecognizerManagerUP m_frame_recognizer_manager_up; /// These are used to set the signal state when you don't have a process and /// more usefully in the Dummy target where you can't know exactly what /// signals you will have. llvm::StringMap m_dummy_signals; static void ImageSearchPathsChanged(const PathMappingList &path_list, void *baton); // Utilities for `statistics` command. private: // Target metrics storage. TargetStats m_stats; public: /// Get metrics associated with this target in JSON format. /// /// Target metrics help measure timings and information that is contained in /// a target. These are designed to help measure performance of a debug /// session as well as represent the current state of the target, like /// information on the currently modules, currently set breakpoints and more. /// /// \return /// Returns a JSON value that contains all target metrics. llvm::json::Value ReportStatistics(const lldb_private::StatisticsOptions &options); TargetStats &GetStatistics() { return m_stats; } private: /// Construct with optional file and arch. /// /// This member is private. Clients must use /// TargetList::CreateTarget(const FileSpec*, const ArchSpec*) /// so all targets can be tracked from the central target list. /// /// \see TargetList::CreateTarget(const FileSpec*, const ArchSpec*) Target(Debugger &debugger, const ArchSpec &target_arch, const lldb::PlatformSP &platform_sp, bool is_dummy_target); // Helper function. bool ProcessIsValid(); // Copy breakpoints, stop hooks and so forth from the dummy target: void PrimeFromDummyTarget(Target &target); void AddBreakpoint(lldb::BreakpointSP breakpoint_sp, bool internal); void FinalizeFileActions(ProcessLaunchInfo &info); /// Return a recommended size for memory reads at \a addr, optimizing for /// cache usage. lldb::addr_t GetReasonableReadSize(const Address &addr); Target(const Target &) = delete; const Target &operator=(const Target &) = delete; }; } // namespace lldb_private #endif // LLDB_TARGET_TARGET_H