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1 //===-- Thread.h ------------------------------------------------*- C++ -*-===//
2 //
3 // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
4 // See https://llvm.org/LICENSE.txt for license information.
5 // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
6 //
7 //===----------------------------------------------------------------------===//
8 
9 #ifndef LLDB_TARGET_THREAD_H
10 #define LLDB_TARGET_THREAD_H
11 
12 #include <memory>
13 #include <mutex>
14 #include <string>
15 #include <vector>
16 
17 #include "lldb/Core/UserSettingsController.h"
18 #include "lldb/Target/ExecutionContextScope.h"
19 #include "lldb/Target/RegisterCheckpoint.h"
20 #include "lldb/Target/StackFrameList.h"
21 #include "lldb/Utility/Broadcaster.h"
22 #include "lldb/Utility/CompletionRequest.h"
23 #include "lldb/Utility/Event.h"
24 #include "lldb/Utility/StructuredData.h"
25 #include "lldb/Utility/UserID.h"
26 #include "lldb/lldb-private.h"
27 
28 #define LLDB_THREAD_MAX_STOP_EXC_DATA 8
29 
30 namespace lldb_private {
31 
32 class ThreadPlanStack;
33 
34 class ThreadProperties : public Properties {
35 public:
36   ThreadProperties(bool is_global);
37 
38   ~ThreadProperties() override;
39 
40   /// The regular expression returned determines symbols that this
41   /// thread won't stop in during "step-in" operations.
42   ///
43   /// \return
44   ///    A pointer to a regular expression to compare against symbols,
45   ///    or nullptr if all symbols are allowed.
46   ///
47   const RegularExpression *GetSymbolsToAvoidRegexp();
48 
49   FileSpecList GetLibrariesToAvoid() const;
50 
51   bool GetTraceEnabledState() const;
52 
53   bool GetStepInAvoidsNoDebug() const;
54 
55   bool GetStepOutAvoidsNoDebug() const;
56 
57   uint64_t GetMaxBacktraceDepth() const;
58 };
59 
60 typedef std::shared_ptr<ThreadProperties> ThreadPropertiesSP;
61 
62 class Thread : public std::enable_shared_from_this<Thread>,
63                public ThreadProperties,
64                public UserID,
65                public ExecutionContextScope,
66                public Broadcaster {
67 public:
68   /// Broadcaster event bits definitions.
69   enum {
70     eBroadcastBitStackChanged = (1 << 0),
71     eBroadcastBitThreadSuspended = (1 << 1),
72     eBroadcastBitThreadResumed = (1 << 2),
73     eBroadcastBitSelectedFrameChanged = (1 << 3),
74     eBroadcastBitThreadSelected = (1 << 4)
75   };
76 
77   static ConstString &GetStaticBroadcasterClass();
78 
GetBroadcasterClass()79   ConstString &GetBroadcasterClass() const override {
80     return GetStaticBroadcasterClass();
81   }
82 
83   class ThreadEventData : public EventData {
84   public:
85     ThreadEventData(const lldb::ThreadSP thread_sp);
86 
87     ThreadEventData(const lldb::ThreadSP thread_sp, const StackID &stack_id);
88 
89     ThreadEventData();
90 
91     ~ThreadEventData() override;
92 
93     static ConstString GetFlavorString();
94 
GetFlavor()95     ConstString GetFlavor() const override {
96       return ThreadEventData::GetFlavorString();
97     }
98 
99     void Dump(Stream *s) const override;
100 
101     static const ThreadEventData *GetEventDataFromEvent(const Event *event_ptr);
102 
103     static lldb::ThreadSP GetThreadFromEvent(const Event *event_ptr);
104 
105     static StackID GetStackIDFromEvent(const Event *event_ptr);
106 
107     static lldb::StackFrameSP GetStackFrameFromEvent(const Event *event_ptr);
108 
GetThread()109     lldb::ThreadSP GetThread() const { return m_thread_sp; }
110 
GetStackID()111     StackID GetStackID() const { return m_stack_id; }
112 
113   private:
114     lldb::ThreadSP m_thread_sp;
115     StackID m_stack_id;
116 
117     ThreadEventData(const ThreadEventData &) = delete;
118     const ThreadEventData &operator=(const ThreadEventData &) = delete;
119   };
120 
121   struct ThreadStateCheckpoint {
122     uint32_t orig_stop_id; // Dunno if I need this yet but it is an interesting
123                            // bit of data.
124     lldb::StopInfoSP stop_info_sp; // You have to restore the stop info or you
125                                    // might continue with the wrong signals.
126     size_t m_completed_plan_checkpoint;
127     lldb::RegisterCheckpointSP
128         register_backup_sp; // You need to restore the registers, of course...
129     uint32_t current_inlined_depth;
130     lldb::addr_t current_inlined_pc;
131   };
132 
133   /// Constructor
134   ///
135   /// \param [in] use_invalid_index_id
136   ///     Optional parameter, defaults to false.  The only subclass that
137   ///     is likely to set use_invalid_index_id == true is the HistoryThread
138   ///     class.  In that case, the Thread we are constructing represents
139   ///     a thread from earlier in the program execution.  We may have the
140   ///     tid of the original thread that they represent but we don't want
141   ///     to reuse the IndexID of that thread, or create a new one.  If a
142   ///     client wants to know the original thread's IndexID, they should use
143   ///     Thread::GetExtendedBacktraceOriginatingIndexID().
144   Thread(Process &process, lldb::tid_t tid, bool use_invalid_index_id = false);
145 
146   ~Thread() override;
147 
148   static void SettingsInitialize();
149 
150   static void SettingsTerminate();
151 
152   static const ThreadPropertiesSP &GetGlobalProperties();
153 
GetProcess()154   lldb::ProcessSP GetProcess() const { return m_process_wp.lock(); }
155 
GetResumeSignal()156   int GetResumeSignal() const { return m_resume_signal; }
157 
SetResumeSignal(int signal)158   void SetResumeSignal(int signal) { m_resume_signal = signal; }
159 
160   lldb::StateType GetState() const;
161 
162   void SetState(lldb::StateType state);
163 
164   /// Sets the USER resume state for this thread.  If you set a thread to
165   /// suspended with
166   /// this API, it won't take part in any of the arbitration for ShouldResume,
167   /// and will stay
168   /// suspended even when other threads do get to run.
169   ///
170   /// N.B. This is not the state that is used internally by thread plans to
171   /// implement
172   /// staying on one thread while stepping over a breakpoint, etc.  The is the
173   /// TemporaryResume state, and if you are implementing some bit of strategy in
174   /// the stepping
175   /// machinery you should be using that state and not the user resume state.
176   ///
177   /// If you are just preparing all threads to run, you should not override the
178   /// threads that are
179   /// marked as suspended by the debugger.  In that case, pass override_suspend
180   /// = false.  If you want
181   /// to force the thread to run (e.g. the "thread continue" command, or are
182   /// resetting the state
183   /// (e.g. in SBThread::Resume()), then pass true to override_suspend.
184   void SetResumeState(lldb::StateType state, bool override_suspend = false) {
185     if (m_resume_state == lldb::eStateSuspended && !override_suspend)
186       return;
187     m_resume_state = state;
188   }
189 
190   /// Gets the USER resume state for this thread.  This is not the same as what
191   /// this thread is going to do for any particular step, however if this thread
192   /// returns eStateSuspended, then the process control logic will never allow
193   /// this
194   /// thread to run.
195   ///
196   /// \return
197   ///    The User resume state for this thread.
GetResumeState()198   lldb::StateType GetResumeState() const { return m_resume_state; }
199 
200   // This function is called on all the threads before "ShouldResume" and
201   // "WillResume" in case a thread needs to change its state before the
202   // ThreadList polls all the threads to figure out which ones actually will
203   // get to run and how.
204   void SetupForResume();
205 
206   // Do not override this function, it is for thread plan logic only
207   bool ShouldResume(lldb::StateType resume_state);
208 
209   // Override this to do platform specific tasks before resume.
WillResume(lldb::StateType resume_state)210   virtual void WillResume(lldb::StateType resume_state) {}
211 
212   // This clears generic thread state after a resume.  If you subclass this, be
213   // sure to call it.
214   virtual void DidResume();
215 
216   // This notifies the thread when a private stop occurs.
217   virtual void DidStop();
218 
219   virtual void RefreshStateAfterStop() = 0;
220 
221   void SelectMostRelevantFrame();
222 
223   std::string GetStopDescription();
224 
225   std::string GetStopDescriptionRaw();
226 
227   void WillStop();
228 
229   bool ShouldStop(Event *event_ptr);
230 
231   Vote ShouldReportStop(Event *event_ptr);
232 
233   Vote ShouldReportRun(Event *event_ptr);
234 
235   void Flush();
236 
237   // Return whether this thread matches the specification in ThreadSpec.  This
238   // is a virtual method because at some point we may extend the thread spec
239   // with a platform specific dictionary of attributes, which then only the
240   // platform specific Thread implementation would know how to match.  For now,
241   // this just calls through to the ThreadSpec's ThreadPassesBasicTests method.
242   virtual bool MatchesSpec(const ThreadSpec *spec);
243 
244   lldb::StopInfoSP GetStopInfo();
245 
246   lldb::StopReason GetStopReason();
247 
248   bool StopInfoIsUpToDate() const;
249 
250   // This sets the stop reason to a "blank" stop reason, so you can call
251   // functions on the thread without having the called function run with
252   // whatever stop reason you stopped with.
253   void SetStopInfoToNothing();
254 
255   bool ThreadStoppedForAReason();
256 
257   static std::string RunModeAsString(lldb::RunMode mode);
258 
259   static std::string StopReasonAsString(lldb::StopReason reason);
260 
GetInfo()261   virtual const char *GetInfo() { return nullptr; }
262 
263   /// Retrieve a dictionary of information about this thread
264   ///
265   /// On Mac OS X systems there may be voucher information.
266   /// The top level dictionary returned will have an "activity" key and the
267   /// value of the activity is a dictionary.  Keys in that dictionary will
268   /// be "name" and "id", among others.
269   /// There may also be "trace_messages" (an array) with each entry in that
270   /// array
271   /// being a dictionary (keys include "message" with the text of the trace
272   /// message).
GetExtendedInfo()273   StructuredData::ObjectSP GetExtendedInfo() {
274     if (!m_extended_info_fetched) {
275       m_extended_info = FetchThreadExtendedInfo();
276       m_extended_info_fetched = true;
277     }
278     return m_extended_info;
279   }
280 
GetName()281   virtual const char *GetName() { return nullptr; }
282 
SetName(const char * name)283   virtual void SetName(const char *name) {}
284 
285   /// Whether this thread can be associated with a libdispatch queue
286   ///
287   /// The Thread may know if it is associated with a libdispatch queue,
288   /// it may know definitively that it is NOT associated with a libdispatch
289   /// queue, or it may be unknown whether it is associated with a libdispatch
290   /// queue.
291   ///
292   /// \return
293   ///     eLazyBoolNo if this thread is definitely not associated with a
294   ///     libdispatch queue (e.g. on a non-Darwin system where GCD aka
295   ///     libdispatch is not available).
296   ///
297   ///     eLazyBoolYes this thread is associated with a libdispatch queue.
298   ///
299   ///     eLazyBoolCalculate this thread may be associated with a libdispatch
300   ///     queue but the thread doesn't know one way or the other.
GetAssociatedWithLibdispatchQueue()301   virtual lldb_private::LazyBool GetAssociatedWithLibdispatchQueue() {
302     return eLazyBoolNo;
303   }
304 
SetAssociatedWithLibdispatchQueue(lldb_private::LazyBool associated_with_libdispatch_queue)305   virtual void SetAssociatedWithLibdispatchQueue(
306       lldb_private::LazyBool associated_with_libdispatch_queue) {}
307 
308   /// Retrieve the Queue ID for the queue currently using this Thread
309   ///
310   /// If this Thread is doing work on behalf of a libdispatch/GCD queue,
311   /// retrieve the QueueID.
312   ///
313   /// This is a unique identifier for the libdispatch/GCD queue in a
314   /// process.  Often starting at 1 for the initial system-created
315   /// queues and incrementing, a QueueID will not be reused for a
316   /// different queue during the lifetime of a process.
317   ///
318   /// \return
319   ///     A QueueID if the Thread subclass implements this, else
320   ///     LLDB_INVALID_QUEUE_ID.
GetQueueID()321   virtual lldb::queue_id_t GetQueueID() { return LLDB_INVALID_QUEUE_ID; }
322 
SetQueueID(lldb::queue_id_t new_val)323   virtual void SetQueueID(lldb::queue_id_t new_val) {}
324 
325   /// Retrieve the Queue name for the queue currently using this Thread
326   ///
327   /// If this Thread is doing work on behalf of a libdispatch/GCD queue,
328   /// retrieve the Queue name.
329   ///
330   /// \return
331   ///     The Queue name, if the Thread subclass implements this, else
332   ///     nullptr.
GetQueueName()333   virtual const char *GetQueueName() { return nullptr; }
334 
SetQueueName(const char * name)335   virtual void SetQueueName(const char *name) {}
336 
337   /// Retrieve the Queue kind for the queue currently using this Thread
338   ///
339   /// If this Thread is doing work on behalf of a libdispatch/GCD queue,
340   /// retrieve the Queue kind - either eQueueKindSerial or
341   /// eQueueKindConcurrent, indicating that this queue processes work
342   /// items serially or concurrently.
343   ///
344   /// \return
345   ///     The Queue kind, if the Thread subclass implements this, else
346   ///     eQueueKindUnknown.
GetQueueKind()347   virtual lldb::QueueKind GetQueueKind() { return lldb::eQueueKindUnknown; }
348 
SetQueueKind(lldb::QueueKind kind)349   virtual void SetQueueKind(lldb::QueueKind kind) {}
350 
351   /// Retrieve the Queue for this thread, if any.
352   ///
353   /// \return
354   ///     A QueueSP for the queue that is currently associated with this
355   ///     thread.
356   ///     An empty shared pointer indicates that this thread is not
357   ///     associated with a queue, or libdispatch queues are not
358   ///     supported on this target.
GetQueue()359   virtual lldb::QueueSP GetQueue() { return lldb::QueueSP(); }
360 
361   /// Retrieve the address of the libdispatch_queue_t struct for queue
362   /// currently using this Thread
363   ///
364   /// If this Thread is doing work on behalf of a libdispatch/GCD queue,
365   /// retrieve the address of the libdispatch_queue_t structure describing
366   /// the queue.
367   ///
368   /// This address may be reused for different queues later in the Process
369   /// lifetime and should not be used to identify a queue uniquely.  Use
370   /// the GetQueueID() call for that.
371   ///
372   /// \return
373   ///     The Queue's libdispatch_queue_t address if the Thread subclass
374   ///     implements this, else LLDB_INVALID_ADDRESS.
GetQueueLibdispatchQueueAddress()375   virtual lldb::addr_t GetQueueLibdispatchQueueAddress() {
376     return LLDB_INVALID_ADDRESS;
377   }
378 
SetQueueLibdispatchQueueAddress(lldb::addr_t dispatch_queue_t)379   virtual void SetQueueLibdispatchQueueAddress(lldb::addr_t dispatch_queue_t) {}
380 
381   /// Whether this Thread already has all the Queue information cached or not
382   ///
383   /// A Thread may be associated with a libdispatch work Queue at a given
384   /// public stop event.  If so, the thread can satisify requests like
385   /// GetQueueLibdispatchQueueAddress, GetQueueKind, GetQueueName, and
386   /// GetQueueID
387   /// either from information from the remote debug stub when it is initially
388   /// created, or it can query the SystemRuntime for that information.
389   ///
390   /// This method allows the SystemRuntime to discover if a thread has this
391   /// information already, instead of calling the thread to get the information
392   /// and having the thread call the SystemRuntime again.
ThreadHasQueueInformation()393   virtual bool ThreadHasQueueInformation() const { return false; }
394 
GetStackFrameCount()395   virtual uint32_t GetStackFrameCount() {
396     return GetStackFrameList()->GetNumFrames();
397   }
398 
GetStackFrameAtIndex(uint32_t idx)399   virtual lldb::StackFrameSP GetStackFrameAtIndex(uint32_t idx) {
400     return GetStackFrameList()->GetFrameAtIndex(idx);
401   }
402 
403   virtual lldb::StackFrameSP
404   GetFrameWithConcreteFrameIndex(uint32_t unwind_idx);
405 
DecrementCurrentInlinedDepth()406   bool DecrementCurrentInlinedDepth() {
407     return GetStackFrameList()->DecrementCurrentInlinedDepth();
408   }
409 
GetCurrentInlinedDepth()410   uint32_t GetCurrentInlinedDepth() {
411     return GetStackFrameList()->GetCurrentInlinedDepth();
412   }
413 
414   Status ReturnFromFrameWithIndex(uint32_t frame_idx,
415                                   lldb::ValueObjectSP return_value_sp,
416                                   bool broadcast = false);
417 
418   Status ReturnFromFrame(lldb::StackFrameSP frame_sp,
419                          lldb::ValueObjectSP return_value_sp,
420                          bool broadcast = false);
421 
422   Status JumpToLine(const FileSpec &file, uint32_t line,
423                     bool can_leave_function, std::string *warnings = nullptr);
424 
GetFrameWithStackID(const StackID & stack_id)425   virtual lldb::StackFrameSP GetFrameWithStackID(const StackID &stack_id) {
426     if (stack_id.IsValid())
427       return GetStackFrameList()->GetFrameWithStackID(stack_id);
428     return lldb::StackFrameSP();
429   }
430 
GetSelectedFrameIndex()431   uint32_t GetSelectedFrameIndex() {
432     return GetStackFrameList()->GetSelectedFrameIndex();
433   }
434 
435   lldb::StackFrameSP GetSelectedFrame();
436 
437   uint32_t SetSelectedFrame(lldb_private::StackFrame *frame,
438                             bool broadcast = false);
439 
440   bool SetSelectedFrameByIndex(uint32_t frame_idx, bool broadcast = false);
441 
442   bool SetSelectedFrameByIndexNoisily(uint32_t frame_idx,
443                                       Stream &output_stream);
444 
SetDefaultFileAndLineToSelectedFrame()445   void SetDefaultFileAndLineToSelectedFrame() {
446     GetStackFrameList()->SetDefaultFileAndLineToSelectedFrame();
447   }
448 
449   virtual lldb::RegisterContextSP GetRegisterContext() = 0;
450 
451   virtual lldb::RegisterContextSP
452   CreateRegisterContextForFrame(StackFrame *frame) = 0;
453 
454   virtual void ClearStackFrames();
455 
SetBackingThread(const lldb::ThreadSP & thread_sp)456   virtual bool SetBackingThread(const lldb::ThreadSP &thread_sp) {
457     return false;
458   }
459 
GetBackingThread()460   virtual lldb::ThreadSP GetBackingThread() const { return lldb::ThreadSP(); }
461 
ClearBackingThread()462   virtual void ClearBackingThread() {
463     // Subclasses can use this function if a thread is actually backed by
464     // another thread. This is currently used for the OperatingSystem plug-ins
465     // where they might have a thread that is in memory, yet its registers are
466     // available through the lldb_private::Thread subclass for the current
467     // lldb_private::Process class. Since each time the process stops the
468     // backing threads for memory threads can change, we need a way to clear
469     // the backing thread for all memory threads each time we stop.
470   }
471 
472   /// Dump \a count instructions of the thread's \a Trace starting at the \a
473   /// start_position position in reverse order.
474   ///
475   /// The instructions are indexed in reverse order, which means that the \a
476   /// start_position 0 represents the last instruction of the trace
477   /// chronologically.
478   ///
479   /// \param[in] s
480   ///   The stream object where the instructions are printed.
481   ///
482   /// \param[in] count
483   ///     The number of instructions to print.
484   ///
485   /// \param[in] start_position
486   ///     The position of the first instruction to print.
487   void DumpTraceInstructions(Stream &s, size_t count,
488                              size_t start_position = 0) const;
489 
490   // If stop_format is true, this will be the form used when we print stop
491   // info. If false, it will be the form we use for thread list and co.
492   void DumpUsingSettingsFormat(Stream &strm, uint32_t frame_idx,
493                                bool stop_format);
494 
495   bool GetDescription(Stream &s, lldb::DescriptionLevel level,
496                       bool print_json_thread, bool print_json_stopinfo);
497 
498   /// Default implementation for stepping into.
499   ///
500   /// This function is designed to be used by commands where the
501   /// process is publicly stopped.
502   ///
503   /// \param[in] source_step
504   ///     If true and the frame has debug info, then do a source level
505   ///     step in, else do a single instruction step in.
506   ///
507   /// \param[in] step_in_avoids_code_without_debug_info
508   ///     If \a true, then avoid stepping into code that doesn't have
509   ///     debug info, else step into any code regardless of whether it
510   ///     has debug info.
511   ///
512   /// \param[in] step_out_avoids_code_without_debug_info
513   ///     If \a true, then if you step out to code with no debug info, keep
514   ///     stepping out till you get to code with debug info.
515   ///
516   /// \return
517   ///     An error that describes anything that went wrong
518   virtual Status
519   StepIn(bool source_step,
520          LazyBool step_in_avoids_code_without_debug_info = eLazyBoolCalculate,
521          LazyBool step_out_avoids_code_without_debug_info = eLazyBoolCalculate);
522 
523   /// Default implementation for stepping over.
524   ///
525   /// This function is designed to be used by commands where the
526   /// process is publicly stopped.
527   ///
528   /// \param[in] source_step
529   ///     If true and the frame has debug info, then do a source level
530   ///     step over, else do a single instruction step over.
531   ///
532   /// \return
533   ///     An error that describes anything that went wrong
534   virtual Status StepOver(
535       bool source_step,
536       LazyBool step_out_avoids_code_without_debug_info = eLazyBoolCalculate);
537 
538   /// Default implementation for stepping out.
539   ///
540   /// This function is designed to be used by commands where the
541   /// process is publicly stopped.
542   ///
543   /// \return
544   ///     An error that describes anything that went wrong
545   virtual Status StepOut();
546 
547   /// Retrieves the per-thread data area.
548   /// Most OSs maintain a per-thread pointer (e.g. the FS register on
549   /// x64), which we return the value of here.
550   ///
551   /// \return
552   ///     LLDB_INVALID_ADDRESS if not supported, otherwise the thread
553   ///     pointer value.
554   virtual lldb::addr_t GetThreadPointer();
555 
556   /// Retrieves the per-module TLS block for a thread.
557   ///
558   /// \param[in] module
559   ///     The module to query TLS data for.
560   ///
561   /// \param[in] tls_file_addr
562   ///     The thread local address in module
563   /// \return
564   ///     If the thread has TLS data allocated for the
565   ///     module, the address of the TLS block. Otherwise
566   ///     LLDB_INVALID_ADDRESS is returned.
567   virtual lldb::addr_t GetThreadLocalData(const lldb::ModuleSP module,
568                                           lldb::addr_t tls_file_addr);
569 
570   /// Check whether this thread is safe to run functions
571   ///
572   /// The SystemRuntime may know of certain thread states (functions in
573   /// process of execution, for instance) which can make it unsafe for
574   /// functions to be called.
575   ///
576   /// \return
577   ///     True if it is safe to call functions on this thread.
578   ///     False if function calls should be avoided on this thread.
579   virtual bool SafeToCallFunctions();
580 
581   // Thread Plan Providers:
582   // This section provides the basic thread plans that the Process control
583   // machinery uses to run the target.  ThreadPlan.h provides more details on
584   // how this mechanism works. The thread provides accessors to a set of plans
585   // that perform basic operations. The idea is that particular Platform
586   // plugins can override these methods to provide the implementation of these
587   // basic operations appropriate to their environment.
588   //
589   // NB: All the QueueThreadPlanXXX providers return Shared Pointers to
590   // Thread plans.  This is useful so that you can modify the plans after
591   // creation in ways specific to that plan type.  Also, it is often necessary
592   // for ThreadPlans that utilize other ThreadPlans to implement their task to
593   // keep a shared pointer to the sub-plan. But besides that, the shared
594   // pointers should only be held onto by entities who live no longer than the
595   // thread containing the ThreadPlan.
596   // FIXME: If this becomes a problem, we can make a version that just returns a
597   // pointer,
598   // which it is clearly unsafe to hold onto, and a shared pointer version, and
599   // only allow ThreadPlan and Co. to use the latter.  That is made more
600   // annoying to do because there's no elegant way to friend a method to all
601   // sub-classes of a given class.
602   //
603 
604   /// Queues the base plan for a thread.
605   /// The version returned by Process does some things that are useful,
606   /// like handle breakpoints and signals, so if you return a plugin specific
607   /// one you probably want to call through to the Process one for anything
608   /// your plugin doesn't explicitly handle.
609   ///
610   /// \param[in] abort_other_plans
611   ///    \b true if we discard the currently queued plans and replace them with
612   ///    this one.
613   ///    Otherwise this plan will go on the end of the plan stack.
614   ///
615   /// \return
616   ///     A shared pointer to the newly queued thread plan, or nullptr if the
617   ///     plan could not be queued.
618   virtual lldb::ThreadPlanSP QueueFundamentalPlan(bool abort_other_plans);
619 
620   /// Queues the plan used to step one instruction from the current PC of \a
621   /// thread.
622   ///
623   /// \param[in] step_over
624   ///    \b true if we step over calls to functions, false if we step in.
625   ///
626   /// \param[in] abort_other_plans
627   ///    \b true if we discard the currently queued plans and replace them with
628   ///    this one.
629   ///    Otherwise this plan will go on the end of the plan stack.
630   ///
631   /// \param[in] stop_other_threads
632   ///    \b true if we will stop other threads while we single step this one.
633   ///
634   /// \param[out] status
635   ///     A status with an error if queuing failed.
636   ///
637   /// \return
638   ///     A shared pointer to the newly queued thread plan, or nullptr if the
639   ///     plan could not be queued.
640   virtual lldb::ThreadPlanSP QueueThreadPlanForStepSingleInstruction(
641       bool step_over, bool abort_other_plans, bool stop_other_threads,
642       Status &status);
643 
644   /// Queues the plan used to step through an address range, stepping  over
645   /// function calls.
646   ///
647   /// \param[in] abort_other_plans
648   ///    \b true if we discard the currently queued plans and replace them with
649   ///    this one.
650   ///    Otherwise this plan will go on the end of the plan stack.
651   ///
652   /// \param[in] type
653   ///    Type of step to do, only eStepTypeInto and eStepTypeOver are supported
654   ///    by this plan.
655   ///
656   /// \param[in] range
657   ///    The address range to step through.
658   ///
659   /// \param[in] addr_context
660   ///    When dealing with stepping through inlined functions the current PC is
661   ///    not enough information to know
662   ///    what "step" means.  For instance a series of nested inline functions
663   ///    might start at the same address.
664   //     The \a addr_context provides the current symbol context the step
665   ///    is supposed to be out of.
666   //   FIXME: Currently unused.
667   ///
668   /// \param[in] stop_other_threads
669   ///    \b true if we will stop other threads while we single step this one.
670   ///
671   /// \param[out] status
672   ///     A status with an error if queuing failed.
673   ///
674   /// \param[in] step_out_avoids_code_without_debug_info
675   ///    If eLazyBoolYes, if the step over steps out it will continue to step
676   ///    out till it comes to a frame with debug info.
677   ///    If eLazyBoolCalculate, we will consult the default set in the thread.
678   ///
679   /// \return
680   ///     A shared pointer to the newly queued thread plan, or nullptr if the
681   ///     plan could not be queued.
682   virtual lldb::ThreadPlanSP QueueThreadPlanForStepOverRange(
683       bool abort_other_plans, const AddressRange &range,
684       const SymbolContext &addr_context, lldb::RunMode stop_other_threads,
685       Status &status,
686       LazyBool step_out_avoids_code_without_debug_info = eLazyBoolCalculate);
687 
688   // Helper function that takes a LineEntry to step, insted of an AddressRange.
689   // This may combine multiple LineEntries of the same source line number to
690   // step over a longer address range in a single operation.
691   virtual lldb::ThreadPlanSP QueueThreadPlanForStepOverRange(
692       bool abort_other_plans, const LineEntry &line_entry,
693       const SymbolContext &addr_context, lldb::RunMode stop_other_threads,
694       Status &status,
695       LazyBool step_out_avoids_code_without_debug_info = eLazyBoolCalculate);
696 
697   /// Queues the plan used to step through an address range, stepping into
698   /// functions.
699   ///
700   /// \param[in] abort_other_plans
701   ///    \b true if we discard the currently queued plans and replace them with
702   ///    this one.
703   ///    Otherwise this plan will go on the end of the plan stack.
704   ///
705   /// \param[in] type
706   ///    Type of step to do, only eStepTypeInto and eStepTypeOver are supported
707   ///    by this plan.
708   ///
709   /// \param[in] range
710   ///    The address range to step through.
711   ///
712   /// \param[in] addr_context
713   ///    When dealing with stepping through inlined functions the current PC is
714   ///    not enough information to know
715   ///    what "step" means.  For instance a series of nested inline functions
716   ///    might start at the same address.
717   //     The \a addr_context provides the current symbol context the step
718   ///    is supposed to be out of.
719   //   FIXME: Currently unused.
720   ///
721   /// \param[in] step_in_target
722   ///    Name if function we are trying to step into.  We will step out if we
723   ///    don't land in that function.
724   ///
725   /// \param[in] stop_other_threads
726   ///    \b true if we will stop other threads while we single step this one.
727   ///
728   /// \param[out] status
729   ///     A status with an error if queuing failed.
730   ///
731   /// \param[in] step_in_avoids_code_without_debug_info
732   ///    If eLazyBoolYes we will step out if we step into code with no debug
733   ///    info.
734   ///    If eLazyBoolCalculate we will consult the default set in the thread.
735   ///
736   /// \param[in] step_out_avoids_code_without_debug_info
737   ///    If eLazyBoolYes, if the step over steps out it will continue to step
738   ///    out till it comes to a frame with debug info.
739   ///    If eLazyBoolCalculate, it will consult the default set in the thread.
740   ///
741   /// \return
742   ///     A shared pointer to the newly queued thread plan, or nullptr if the
743   ///     plan could not be queued.
744   virtual lldb::ThreadPlanSP QueueThreadPlanForStepInRange(
745       bool abort_other_plans, const AddressRange &range,
746       const SymbolContext &addr_context, const char *step_in_target,
747       lldb::RunMode stop_other_threads, Status &status,
748       LazyBool step_in_avoids_code_without_debug_info = eLazyBoolCalculate,
749       LazyBool step_out_avoids_code_without_debug_info = eLazyBoolCalculate);
750 
751   // Helper function that takes a LineEntry to step, insted of an AddressRange.
752   // This may combine multiple LineEntries of the same source line number to
753   // step over a longer address range in a single operation.
754   virtual lldb::ThreadPlanSP QueueThreadPlanForStepInRange(
755       bool abort_other_plans, const LineEntry &line_entry,
756       const SymbolContext &addr_context, const char *step_in_target,
757       lldb::RunMode stop_other_threads, Status &status,
758       LazyBool step_in_avoids_code_without_debug_info = eLazyBoolCalculate,
759       LazyBool step_out_avoids_code_without_debug_info = eLazyBoolCalculate);
760 
761   /// Queue the plan used to step out of the function at the current PC of
762   /// \a thread.
763   ///
764   /// \param[in] abort_other_plans
765   ///    \b true if we discard the currently queued plans and replace them with
766   ///    this one.
767   ///    Otherwise this plan will go on the end of the plan stack.
768   ///
769   /// \param[in] addr_context
770   ///    When dealing with stepping through inlined functions the current PC is
771   ///    not enough information to know
772   ///    what "step" means.  For instance a series of nested inline functions
773   ///    might start at the same address.
774   //     The \a addr_context provides the current symbol context the step
775   ///    is supposed to be out of.
776   //   FIXME: Currently unused.
777   ///
778   /// \param[in] first_insn
779   ///     \b true if this is the first instruction of a function.
780   ///
781   /// \param[in] stop_other_threads
782   ///    \b true if we will stop other threads while we single step this one.
783   ///
784   /// \param[in] stop_vote
785   ///    See standard meanings for the stop & run votes in ThreadPlan.h.
786   ///
787   /// \param[in] run_vote
788   ///    See standard meanings for the stop & run votes in ThreadPlan.h.
789   ///
790   /// \param[out] status
791   ///     A status with an error if queuing failed.
792   ///
793   /// \param[in] step_out_avoids_code_without_debug_info
794   ///    If eLazyBoolYes, if the step over steps out it will continue to step
795   ///    out till it comes to a frame with debug info.
796   ///    If eLazyBoolCalculate, it will consult the default set in the thread.
797   ///
798   /// \return
799   ///     A shared pointer to the newly queued thread plan, or nullptr if the
800   ///     plan could not be queued.
801   virtual lldb::ThreadPlanSP QueueThreadPlanForStepOut(
802       bool abort_other_plans, SymbolContext *addr_context, bool first_insn,
803       bool stop_other_threads, Vote stop_vote, Vote run_vote,
804       uint32_t frame_idx, Status &status,
805       LazyBool step_out_avoids_code_without_debug_info = eLazyBoolCalculate);
806 
807   /// Queue the plan used to step out of the function at the current PC of
808   /// a thread.  This version does not consult the should stop here callback,
809   /// and should only
810   /// be used by other thread plans when they need to retain control of the step
811   /// out.
812   ///
813   /// \param[in] abort_other_plans
814   ///    \b true if we discard the currently queued plans and replace them with
815   ///    this one.
816   ///    Otherwise this plan will go on the end of the plan stack.
817   ///
818   /// \param[in] addr_context
819   ///    When dealing with stepping through inlined functions the current PC is
820   ///    not enough information to know
821   ///    what "step" means.  For instance a series of nested inline functions
822   ///    might start at the same address.
823   //     The \a addr_context provides the current symbol context the step
824   ///    is supposed to be out of.
825   //   FIXME: Currently unused.
826   ///
827   /// \param[in] first_insn
828   ///     \b true if this is the first instruction of a function.
829   ///
830   /// \param[in] stop_other_threads
831   ///    \b true if we will stop other threads while we single step this one.
832   ///
833   /// \param[in] stop_vote
834   ///    See standard meanings for the stop & run votes in ThreadPlan.h.
835   ///
836   /// \param[in] run_vote
837   ///    See standard meanings for the stop & run votes in ThreadPlan.h.
838   ///
839   /// \param[in] frame_idx
840   ///     The fame index.
841   ///
842   /// \param[out] status
843   ///     A status with an error if queuing failed.
844   ///
845   /// \param[in] continue_to_next_branch
846   ///    Normally this will enqueue a plan that will put a breakpoint on the
847   ///    return address and continue
848   ///    to there.  If continue_to_next_branch is true, this is an operation not
849   ///    involving the user --
850   ///    e.g. stepping "next" in a source line and we instruction stepped into
851   ///    another function --
852   ///    so instead of putting a breakpoint on the return address, advance the
853   ///    breakpoint to the
854   ///    end of the source line that is doing the call, or until the next flow
855   ///    control instruction.
856   ///    If the return value from the function call is to be retrieved /
857   ///    displayed to the user, you must stop
858   ///    on the return address.  The return value may be stored in volatile
859   ///    registers which are overwritten
860   ///    before the next branch instruction.
861   ///
862   /// \return
863   ///     A shared pointer to the newly queued thread plan, or nullptr if the
864   ///     plan could not be queued.
865   virtual lldb::ThreadPlanSP QueueThreadPlanForStepOutNoShouldStop(
866       bool abort_other_plans, SymbolContext *addr_context, bool first_insn,
867       bool stop_other_threads, Vote stop_vote, Vote run_vote,
868       uint32_t frame_idx, Status &status, bool continue_to_next_branch = false);
869 
870   /// Gets the plan used to step through the code that steps from a function
871   /// call site at the current PC into the actual function call.
872   ///
873   /// \param[in] return_stack_id
874   ///    The stack id that we will return to (by setting backstop breakpoints on
875   ///    the return
876   ///    address to that frame) if we fail to step through.
877   ///
878   /// \param[in] abort_other_plans
879   ///    \b true if we discard the currently queued plans and replace them with
880   ///    this one.
881   ///    Otherwise this plan will go on the end of the plan stack.
882   ///
883   /// \param[in] stop_other_threads
884   ///    \b true if we will stop other threads while we single step this one.
885   ///
886   /// \param[out] status
887   ///     A status with an error if queuing failed.
888   ///
889   /// \return
890   ///     A shared pointer to the newly queued thread plan, or nullptr if the
891   ///     plan could not be queued.
892   virtual lldb::ThreadPlanSP
893   QueueThreadPlanForStepThrough(StackID &return_stack_id,
894                                 bool abort_other_plans, bool stop_other_threads,
895                                 Status &status);
896 
897   /// Gets the plan used to continue from the current PC.
898   /// This is a simple plan, mostly useful as a backstop when you are continuing
899   /// for some particular purpose.
900   ///
901   /// \param[in] abort_other_plans
902   ///    \b true if we discard the currently queued plans and replace them with
903   ///    this one.
904   ///    Otherwise this plan will go on the end of the plan stack.
905   ///
906   /// \param[in] target_addr
907   ///    The address to which we're running.
908   ///
909   /// \param[in] stop_other_threads
910   ///    \b true if we will stop other threads while we single step this one.
911   ///
912   /// \param[out] status
913   ///     A status with an error if queuing failed.
914   ///
915   /// \return
916   ///     A shared pointer to the newly queued thread plan, or nullptr if the
917   ///     plan could not be queued.
918   virtual lldb::ThreadPlanSP
919   QueueThreadPlanForRunToAddress(bool abort_other_plans, Address &target_addr,
920                                  bool stop_other_threads, Status &status);
921 
922   virtual lldb::ThreadPlanSP QueueThreadPlanForStepUntil(
923       bool abort_other_plans, lldb::addr_t *address_list, size_t num_addresses,
924       bool stop_others, uint32_t frame_idx, Status &status);
925 
926   virtual lldb::ThreadPlanSP
927   QueueThreadPlanForStepScripted(bool abort_other_plans, const char *class_name,
928                                  StructuredData::ObjectSP extra_args_sp,
929                                  bool stop_other_threads, Status &status);
930 
931   // Thread Plan accessors:
932 
933   /// Format the thread plan information for auto completion.
934   ///
935   /// \param[in] request
936   ///     The reference to the completion handler.
937   void AutoCompleteThreadPlans(CompletionRequest &request) const;
938 
939   /// Gets the plan which will execute next on the plan stack.
940   ///
941   /// \return
942   ///     A pointer to the next executed plan.
943   ThreadPlan *GetCurrentPlan() const;
944 
945   /// Unwinds the thread stack for the innermost expression plan currently
946   /// on the thread plan stack.
947   ///
948   /// \return
949   ///     An error if the thread plan could not be unwound.
950 
951   Status UnwindInnermostExpression();
952 
953   /// Gets the outer-most plan that was popped off the plan stack in the
954   /// most recent stop.  Useful for printing the stop reason accurately.
955   ///
956   /// \return
957   ///     A pointer to the last completed plan.
958   lldb::ThreadPlanSP GetCompletedPlan() const;
959 
960   /// Gets the outer-most return value from the completed plans
961   ///
962   /// \return
963   ///     A ValueObjectSP, either empty if there is no return value,
964   ///     or containing the return value.
965   lldb::ValueObjectSP GetReturnValueObject() const;
966 
967   /// Gets the outer-most expression variable from the completed plans
968   ///
969   /// \return
970   ///     A ExpressionVariableSP, either empty if there is no
971   ///     plan completed an expression during the current stop
972   ///     or the expression variable that was made for the completed expression.
973   lldb::ExpressionVariableSP GetExpressionVariable() const;
974 
975   ///  Checks whether the given plan is in the completed plans for this
976   ///  stop.
977   ///
978   /// \param[in] plan
979   ///     Pointer to the plan you're checking.
980   ///
981   /// \return
982   ///     Returns true if the input plan is in the completed plan stack,
983   ///     false otherwise.
984   bool IsThreadPlanDone(ThreadPlan *plan) const;
985 
986   ///  Checks whether the given plan is in the discarded plans for this
987   ///  stop.
988   ///
989   /// \param[in] plan
990   ///     Pointer to the plan you're checking.
991   ///
992   /// \return
993   ///     Returns true if the input plan is in the discarded plan stack,
994   ///     false otherwise.
995   bool WasThreadPlanDiscarded(ThreadPlan *plan) const;
996 
997   /// Check if we have completed plan to override breakpoint stop reason
998   ///
999   /// \return
1000   ///     Returns true if completed plan stack is not empty
1001   ///     false otherwise.
1002   bool CompletedPlanOverridesBreakpoint() const;
1003 
1004   /// Queues a generic thread plan.
1005   ///
1006   /// \param[in] plan_sp
1007   ///    The plan to queue.
1008   ///
1009   /// \param[in] abort_other_plans
1010   ///    \b true if we discard the currently queued plans and replace them with
1011   ///    this one.
1012   ///    Otherwise this plan will go on the end of the plan stack.
1013   ///
1014   /// \return
1015   ///     A pointer to the last completed plan.
1016   Status QueueThreadPlan(lldb::ThreadPlanSP &plan_sp, bool abort_other_plans);
1017 
1018   /// Discards the plans queued on the plan stack of the current thread.  This
1019   /// is
1020   /// arbitrated by the "Master" ThreadPlans, using the "OkayToDiscard" call.
1021   //  But if \a force is true, all thread plans are discarded.
1022   void DiscardThreadPlans(bool force);
1023 
1024   /// Discards the plans queued on the plan stack of the current thread up to
1025   /// and
1026   /// including up_to_plan_sp.
1027   //
1028   // \param[in] up_to_plan_sp
1029   //   Discard all plans up to and including this one.
1030   void DiscardThreadPlansUpToPlan(lldb::ThreadPlanSP &up_to_plan_sp);
1031 
1032   void DiscardThreadPlansUpToPlan(ThreadPlan *up_to_plan_ptr);
1033 
1034   /// Discards the plans queued on the plan stack of the current thread up to
1035   /// and
1036   /// including the plan in that matches \a thread_index counting only
1037   /// the non-Private plans.
1038   ///
1039   /// \param[in] thread_index
1040   ///   Discard all plans up to and including this user plan given by this
1041   ///   index.
1042   ///
1043   /// \return
1044   ///    \b true if there was a thread plan with that user index, \b false
1045   ///    otherwise.
1046   bool DiscardUserThreadPlansUpToIndex(uint32_t thread_index);
1047 
1048   virtual bool CheckpointThreadState(ThreadStateCheckpoint &saved_state);
1049 
1050   virtual bool
1051   RestoreRegisterStateFromCheckpoint(ThreadStateCheckpoint &saved_state);
1052 
1053   virtual bool
1054   RestoreThreadStateFromCheckpoint(ThreadStateCheckpoint &saved_state);
1055 
1056   void EnableTracer(bool value, bool single_step);
1057 
1058   void SetTracer(lldb::ThreadPlanTracerSP &tracer_sp);
1059 
1060   // Get the thread index ID. The index ID that is guaranteed to not be re-used
1061   // by a process. They start at 1 and increase with each new thread. This
1062   // allows easy command line access by a unique ID that is easier to type than
1063   // the actual system thread ID.
1064   uint32_t GetIndexID() const;
1065 
1066   // Get the originating thread's index ID.
1067   // In the case of an "extended" thread -- a thread which represents the stack
1068   // that enqueued/spawned work that is currently executing -- we need to
1069   // provide the IndexID of the thread that actually did this work.  We don't
1070   // want to just masquerade as that thread's IndexID by using it in our own
1071   // IndexID because that way leads to madness - but the driver program which
1072   // is iterating over extended threads may ask for the OriginatingThreadID to
1073   // display that information to the user.
1074   // Normal threads will return the same thing as GetIndexID();
GetExtendedBacktraceOriginatingIndexID()1075   virtual uint32_t GetExtendedBacktraceOriginatingIndexID() {
1076     return GetIndexID();
1077   }
1078 
1079   // The API ID is often the same as the Thread::GetID(), but not in all cases.
1080   // Thread::GetID() is the user visible thread ID that clients would want to
1081   // see. The API thread ID is the thread ID that is used when sending data
1082   // to/from the debugging protocol.
GetProtocolID()1083   virtual lldb::user_id_t GetProtocolID() const { return GetID(); }
1084 
1085   // lldb::ExecutionContextScope pure virtual functions
1086   lldb::TargetSP CalculateTarget() override;
1087 
1088   lldb::ProcessSP CalculateProcess() override;
1089 
1090   lldb::ThreadSP CalculateThread() override;
1091 
1092   lldb::StackFrameSP CalculateStackFrame() override;
1093 
1094   void CalculateExecutionContext(ExecutionContext &exe_ctx) override;
1095 
1096   lldb::StackFrameSP
1097   GetStackFrameSPForStackFramePtr(StackFrame *stack_frame_ptr);
1098 
1099   size_t GetStatus(Stream &strm, uint32_t start_frame, uint32_t num_frames,
1100                    uint32_t num_frames_with_source, bool stop_format,
1101                    bool only_stacks = false);
1102 
1103   size_t GetStackFrameStatus(Stream &strm, uint32_t first_frame,
1104                              uint32_t num_frames, bool show_frame_info,
1105                              uint32_t num_frames_with_source);
1106 
1107   // We need a way to verify that even though we have a thread in a shared
1108   // pointer that the object itself is still valid. Currently this won't be the
1109   // case if DestroyThread() was called. DestroyThread is called when a thread
1110   // has been removed from the Process' thread list.
IsValid()1111   bool IsValid() const { return !m_destroy_called; }
1112 
1113   // Sets and returns a valid stop info based on the process stop ID and the
1114   // current thread plan. If the thread stop ID does not match the process'
1115   // stop ID, the private stop reason is not set and an invalid StopInfoSP may
1116   // be returned.
1117   //
1118   // NOTE: This function must be called before the current thread plan is
1119   // moved to the completed plan stack (in Thread::ShouldStop()).
1120   //
1121   // NOTE: If subclasses override this function, ensure they do not overwrite
1122   // the m_actual_stop_info if it is valid.  The stop info may be a
1123   // "checkpointed and restored" stop info, so if it is still around it is
1124   // right even if you have not calculated this yourself, or if it disagrees
1125   // with what you might have calculated.
1126   virtual lldb::StopInfoSP GetPrivateStopInfo();
1127 
1128   // Calculate the stop info that will be shown to lldb clients.  For instance,
1129   // a "step out" is implemented by running to a breakpoint on the function
1130   // return PC, so the process plugin initially sets the stop info to a
1131   // StopInfoBreakpoint. But once we've run the ShouldStop machinery, we
1132   // discover that there's a completed ThreadPlanStepOut, and that's really
1133   // the StopInfo we want to show.  That will happen naturally the next
1134   // time GetStopInfo is called, but if you want to force the replacement,
1135   // you can call this.
1136 
1137   void CalculatePublicStopInfo();
1138 
1139   // Ask the thread subclass to set its stop info.
1140   //
1141   // Thread subclasses should call Thread::SetStopInfo(...) with the reason the
1142   // thread stopped.
1143   //
1144   // \return
1145   //      True if Thread::SetStopInfo(...) was called, false otherwise.
1146   virtual bool CalculateStopInfo() = 0;
1147 
1148   // Gets the temporary resume state for a thread.
1149   //
1150   // This value gets set in each thread by complex debugger logic in
1151   // Thread::ShouldResume() and an appropriate thread resume state will get set
1152   // in each thread every time the process is resumed prior to calling
1153   // Process::DoResume(). The lldb_private::Process subclass should adhere to
1154   // the thread resume state request which will be one of:
1155   //
1156   //  eStateRunning   - thread will resume when process is resumed
1157   //  eStateStepping  - thread should step 1 instruction and stop when process
1158   //                    is resumed
1159   //  eStateSuspended - thread should not execute any instructions when
1160   //                    process is resumed
GetTemporaryResumeState()1161   lldb::StateType GetTemporaryResumeState() const {
1162     return m_temporary_resume_state;
1163   }
1164 
1165   void SetStopInfo(const lldb::StopInfoSP &stop_info_sp);
1166 
1167   void ResetStopInfo();
1168 
1169   void SetShouldReportStop(Vote vote);
1170 
1171   /// Sets the extended backtrace token for this thread
1172   ///
1173   /// Some Thread subclasses may maintain a token to help with providing
1174   /// an extended backtrace.  The SystemRuntime plugin will set/request this.
1175   ///
1176   /// \param [in] token The extended backtrace token.
SetExtendedBacktraceToken(uint64_t token)1177   virtual void SetExtendedBacktraceToken(uint64_t token) {}
1178 
1179   /// Gets the extended backtrace token for this thread
1180   ///
1181   /// Some Thread subclasses may maintain a token to help with providing
1182   /// an extended backtrace.  The SystemRuntime plugin will set/request this.
1183   ///
1184   /// \return
1185   ///     The token needed by the SystemRuntime to create an extended backtrace.
1186   ///     LLDB_INVALID_ADDRESS is returned if no token is available.
GetExtendedBacktraceToken()1187   virtual uint64_t GetExtendedBacktraceToken() { return LLDB_INVALID_ADDRESS; }
1188 
1189   lldb::ValueObjectSP GetCurrentException();
1190 
1191   lldb::ThreadSP GetCurrentExceptionBacktrace();
1192 
1193 protected:
1194   friend class ThreadPlan;
1195   friend class ThreadList;
1196   friend class ThreadEventData;
1197   friend class StackFrameList;
1198   friend class StackFrame;
1199   friend class OperatingSystem;
1200 
1201   // This is necessary to make sure thread assets get destroyed while the
1202   // thread is still in good shape to call virtual thread methods.  This must
1203   // be called by classes that derive from Thread in their destructor.
1204   virtual void DestroyThread();
1205 
1206   ThreadPlanStack &GetPlans() const;
1207 
1208   void PushPlan(lldb::ThreadPlanSP plan_sp);
1209 
1210   void PopPlan();
1211 
1212   void DiscardPlan();
1213 
1214   ThreadPlan *GetPreviousPlan(ThreadPlan *plan) const;
1215 
1216   virtual Unwind &GetUnwinder();
1217 
1218   // Check to see whether the thread is still at the last breakpoint hit that
1219   // stopped it.
1220   virtual bool IsStillAtLastBreakpointHit();
1221 
1222   // Some threads are threads that are made up by OperatingSystem plugins that
1223   // are threads that exist and are context switched out into memory. The
1224   // OperatingSystem plug-in need a ways to know if a thread is "real" or made
1225   // up.
IsOperatingSystemPluginThread()1226   virtual bool IsOperatingSystemPluginThread() const { return false; }
1227 
1228   // Subclasses that have a way to get an extended info dictionary for this
1229   // thread should fill
FetchThreadExtendedInfo()1230   virtual lldb_private::StructuredData::ObjectSP FetchThreadExtendedInfo() {
1231     return StructuredData::ObjectSP();
1232   }
1233 
1234   lldb::StackFrameListSP GetStackFrameList();
1235 
SetTemporaryResumeState(lldb::StateType new_state)1236   void SetTemporaryResumeState(lldb::StateType new_state) {
1237     m_temporary_resume_state = new_state;
1238   }
1239 
1240   void FrameSelectedCallback(lldb_private::StackFrame *frame);
1241 
1242   // Classes that inherit from Process can see and modify these
1243   lldb::ProcessWP m_process_wp;    ///< The process that owns this thread.
1244   lldb::StopInfoSP m_stop_info_sp; ///< The private stop reason for this thread
1245   uint32_t m_stop_info_stop_id; // This is the stop id for which the StopInfo is
1246                                 // valid.  Can use this so you know that
1247   // the thread's m_stop_info_sp is current and you don't have to fetch it
1248   // again
1249   uint32_t m_stop_info_override_stop_id; // The stop ID containing the last time
1250                                          // the stop info was checked against
1251                                          // the stop info override
1252   const uint32_t m_index_id; ///< A unique 1 based index assigned to each thread
1253                              ///for easy UI/command line access.
1254   lldb::RegisterContextSP m_reg_context_sp; ///< The register context for this
1255                                             ///thread's current register state.
1256   lldb::StateType m_state;                  ///< The state of our process.
1257   mutable std::recursive_mutex
1258       m_state_mutex;       ///< Multithreaded protection for m_state.
1259   mutable std::recursive_mutex
1260       m_frame_mutex; ///< Multithreaded protection for m_state.
1261   lldb::StackFrameListSP m_curr_frames_sp; ///< The stack frames that get lazily
1262                                            ///populated after a thread stops.
1263   lldb::StackFrameListSP m_prev_frames_sp; ///< The previous stack frames from
1264                                            ///the last time this thread stopped.
1265   int m_resume_signal; ///< The signal that should be used when continuing this
1266                        ///thread.
1267   lldb::StateType m_resume_state; ///< This state is used to force a thread to
1268                                   ///be suspended from outside the ThreadPlan
1269                                   ///logic.
1270   lldb::StateType m_temporary_resume_state; ///< This state records what the
1271                                             ///thread was told to do by the
1272                                             ///thread plan logic for the current
1273                                             ///resume.
1274   /// It gets set in Thread::ShouldResume.
1275   std::unique_ptr<lldb_private::Unwind> m_unwinder_up;
1276   bool m_destroy_called; // This is used internally to make sure derived Thread
1277                          // classes call DestroyThread.
1278   LazyBool m_override_should_notify;
1279   mutable std::unique_ptr<ThreadPlanStack> m_null_plan_stack_up;
1280 
1281 private:
1282   bool m_extended_info_fetched; // Have we tried to retrieve the m_extended_info
1283                                 // for this thread?
1284   StructuredData::ObjectSP m_extended_info; // The extended info for this thread
1285 
1286   void BroadcastSelectedFrameChange(StackID &new_frame_id);
1287 
1288   Thread(const Thread &) = delete;
1289   const Thread &operator=(const Thread &) = delete;
1290 };
1291 
1292 } // namespace lldb_private
1293 
1294 #endif // LLDB_TARGET_THREAD_H
1295