clang-r437112/include/lldb/Target/StackFrame.h - platform/prebuilts/clang/host/darwin-x86 - Git at Google

 //===-- StackFrame.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_STACKFRAME_H
 #define LLDB_TARGET_STACKFRAME_H

 #include <memory>
 #include <mutex>

 #include "lldb/Utility/Flags.h"

 #include "lldb/Core/ValueObjectList.h"
 #include "lldb/Symbol/SymbolContext.h"
 #include "lldb/Target/ExecutionContextScope.h"
 #include "lldb/Target/StackID.h"
 #include "lldb/Utility/Scalar.h"
 #include "lldb/Utility/Status.h"
 #include "lldb/Utility/StreamString.h"
 #include "lldb/Utility/UserID.h"

 namespace lldb_private {

 /// \class StackFrame StackFrame.h "lldb/Target/StackFrame.h"
 ///
 /// This base class provides an interface to stack frames.
 ///
 /// StackFrames may have a Canonical Frame Address (CFA) or not.
 /// A frame may have a plain pc value or it may  indicate a specific point in
 /// the debug session so the correct section load list is used for
 /// symbolication.
 ///
 /// Local variables may be available, or not.  A register context may be
 /// available, or not.

 class StackFrame : public ExecutionContextScope,
                    public std::enable_shared_from_this<StackFrame> {
 public:
   enum ExpressionPathOption {
     eExpressionPathOptionCheckPtrVsMember = (1u << 0),
     eExpressionPathOptionsNoFragileObjcIvar = (1u << 1),
     eExpressionPathOptionsNoSyntheticChildren = (1u << 2),
     eExpressionPathOptionsNoSyntheticArrayRange = (1u << 3),
     eExpressionPathOptionsAllowDirectIVarAccess = (1u << 4),
     eExpressionPathOptionsInspectAnonymousUnions = (1u << 5)
   };

   enum class Kind {
     /// A regular stack frame with access to registers and local variables.
     Regular,

     /// A historical stack frame -- possibly without CFA or registers or
     /// local variables.
     History,

     /// An artificial stack frame (e.g. a synthesized result of inferring
     /// missing tail call frames from a backtrace) with limited support for
     /// local variables.
     Artificial
   };

   /// Construct a StackFrame object without supplying a RegisterContextSP.
   ///
   /// This is the one constructor that doesn't take a RegisterContext
   /// parameter.  This ctor may be called when creating a history StackFrame;
   /// these are used if we've collected a stack trace of pc addresses at some
   /// point in the past.  We may only have pc values. We may have a CFA,
   /// or more likely, we won't.
   ///
   /// \param [in] thread_sp
   ///   The Thread that this frame belongs to.
   ///
   /// \param [in] frame_idx
   ///   This StackFrame's frame index number in the Thread.  If inlined stack
   ///   frames are being created, this may differ from the concrete_frame_idx
   ///   which is the frame index without any inlined stack frames.
   ///
   /// \param [in] concrete_frame_idx
   ///   The StackFrame's frame index number in the Thread without any inlined
   ///   stack frames being included in the index.
   ///
   /// \param [in] cfa
   ///   The Canonical Frame Address (this terminology from DWARF) for this
   ///   stack frame.  The CFA for a stack frame does not change over the
   ///   span of the stack frame's existence.  It is often the value of the
   ///   caller's stack pointer before the call instruction into this frame's
   ///   function.  It is usually not the same as the frame pointer register's
   ///   value.
   ///
   /// \param [in] cfa_is_valid
   ///   A history stack frame may not have a CFA value collected.  We want to
   ///   distinguish between "no CFA available" and a CFA of
   ///   LLDB_INVALID_ADDRESS.
   ///
   /// \param [in] pc
   ///   The current pc value of this stack frame.
   ///
   /// \param [in] sc_ptr
   ///   Optionally seed the StackFrame with the SymbolContext information that
   ///   has
   ///   already been discovered.
   StackFrame(const lldb::ThreadSP &thread_sp, lldb::user_id_t frame_idx,
              lldb::user_id_t concrete_frame_idx, lldb::addr_t cfa,
              bool cfa_is_valid, lldb::addr_t pc, Kind frame_kind,
              bool behaves_like_zeroth_frame, const SymbolContext *sc_ptr);

   StackFrame(const lldb::ThreadSP &thread_sp, lldb::user_id_t frame_idx,
              lldb::user_id_t concrete_frame_idx,
              const lldb::RegisterContextSP &reg_context_sp, lldb::addr_t cfa,
              lldb::addr_t pc, bool behaves_like_zeroth_frame,
              const SymbolContext *sc_ptr);

   StackFrame(const lldb::ThreadSP &thread_sp, lldb::user_id_t frame_idx,
              lldb::user_id_t concrete_frame_idx,
              const lldb::RegisterContextSP &reg_context_sp, lldb::addr_t cfa,
              const Address &pc, bool behaves_like_zeroth_frame,
              const SymbolContext *sc_ptr);

   ~StackFrame() override;

   lldb::ThreadSP GetThread() const { return m_thread_wp.lock(); }

   StackID &GetStackID();

   /// Get an Address for the current pc value in this StackFrame.
   ///
   /// May not be the same as the actual PC value for inlined stack frames.
   ///
   /// \return
   ///   The Address object set to the current PC value.
   const Address &GetFrameCodeAddress();

   /// Get the current code Address suitable for symbolication,
   /// may not be the same as GetFrameCodeAddress().
   ///
   /// For a frame in the middle of the stack, the return-pc is the
   /// current code address, but for symbolication purposes the
   /// return address after a noreturn call may point to the next
   /// function, a DWARF location list entry that is a completely
   /// different code path, or the wrong source line.
   ///
   /// The address returned should be used for symbolication (source line,
   /// block, function, DWARF location entry selection) but should NOT
   /// be shown to the user.  It may not point to an actual instruction
   /// boundary.
   ///
   /// \return
   ///   The Address object set to the current PC value.
   Address GetFrameCodeAddressForSymbolication();

   /// Change the pc value for a given thread.
   ///
   /// Change the current pc value for the frame on this thread.
   ///
   /// \param[in] pc
   ///     The load address that the pc will be set to.
   ///
   /// \return
   ///     true if the pc was changed.  false if this failed -- possibly
   ///     because this frame is not a live StackFrame.
   bool ChangePC(lldb::addr_t pc);

   /// Provide a SymbolContext for this StackFrame's current pc value.
   ///
   /// The StackFrame maintains this SymbolContext and adds additional
   /// information to it on an as-needed basis.  This helps to avoid different
   /// functions looking up symbolic information for a given pc value multiple
   /// times.
   ///
   /// \params [in] resolve_scope
   ///   Flags from the SymbolContextItem enumerated type which specify what
   ///   type of symbol context is needed by this caller.
   ///
   /// \return
   ///   A SymbolContext reference which includes the types of information
   ///   requested by resolve_scope, if they are available.
   const SymbolContext &GetSymbolContext(lldb::SymbolContextItem resolve_scope);

   /// Return the Canonical Frame Address (DWARF term) for this frame.
   ///
   /// The CFA is typically the value of the stack pointer register before the
   /// call invocation is made.  It will not change during the lifetime of a
   /// stack frame.  It is often not the same thing as the frame pointer
   /// register value.
   ///
   /// Live StackFrames will always have a CFA but other types of frames may
   /// not be able to supply one.
   ///
   /// \param [out] value
   ///   The address of the CFA for this frame, if available.
   ///
   /// \param [out] error_ptr
   ///   If there is an error determining the CFA address, this may contain a
   ///   string explaining the failure.
   ///
   /// \return
   ///   Returns true if the CFA value was successfully set in value.  Some
   ///   frames may be unable to provide this value; they will return false.
   bool GetFrameBaseValue(Scalar &value, Status *error_ptr);

   /// Get the DWARFExpression corresponding to the Canonical Frame Address.
   ///
   /// Often a register (bp), but sometimes a register + offset.
   ///
   /// \param [out] error_ptr
   ///   If there is an error determining the CFA address, this may contain a
   ///   string explaining the failure.
   ///
   /// \return
   ///   Returns the corresponding DWARF expression, or NULL.
   DWARFExpression *GetFrameBaseExpression(Status *error_ptr);

   /// Get the current lexical scope block for this StackFrame, if possible.
   ///
   /// If debug information is available for this stack frame, return a pointer
   /// to the innermost lexical Block that the frame is currently executing.
   ///
   /// \return
   ///   A pointer to the current Block.  nullptr is returned if this can
   ///   not be provided.
   Block *GetFrameBlock();

   /// Get the RegisterContext for this frame, if possible.
   ///
   /// Returns a shared pointer to the RegisterContext for this stack frame.
   /// Only a live StackFrame object will be able to return a RegisterContext -
   /// callers must be prepared for an empty shared pointer being returned.
   ///
   /// Even a live StackFrame RegisterContext may not be able to provide all
   /// registers.  Only the currently executing frame (frame 0) can reliably
   /// provide every register in the register context.
   ///
   /// \return
   ///   The RegisterContext shared point for this frame.
   lldb::RegisterContextSP GetRegisterContext();

   const lldb::RegisterContextSP &GetRegisterContextSP() const {
     return m_reg_context_sp;
   }

   /// Retrieve the list of variables that are in scope at this StackFrame's
   /// pc.
   ///
   /// A frame that is not live may return an empty VariableList for a given
   /// pc value even though variables would be available at this point if it
   /// were a live stack frame.
   ///
   /// \param[in] get_file_globals
   ///     Whether to also retrieve compilation-unit scoped variables
   ///     that are visible to the entire compilation unit (e.g. file
   ///     static in C, globals that are homed in this CU).
   ///
   /// \return
   ///     A pointer to a list of variables.
   VariableList *GetVariableList(bool get_file_globals);

   /// Retrieve the list of variables that are in scope at this StackFrame's
   /// pc.
   ///
   /// A frame that is not live may return an empty VariableListSP for a
   /// given pc value even though variables would be available at this point if
   /// it were a live stack frame.
   ///
   /// \param[in] get_file_globals
   ///     Whether to also retrieve compilation-unit scoped variables
   ///     that are visible to the entire compilation unit (e.g. file
   ///     static in C, globals that are homed in this CU).
   ///
   /// \return
   ///     A pointer to a list of variables.
   lldb::VariableListSP
   GetInScopeVariableList(bool get_file_globals,
                          bool must_have_valid_location = false);

   /// Create a ValueObject for a variable name / pathname, possibly including
   /// simple dereference/child selection syntax.
   ///
   /// \param[in] var_expr
   ///     The string specifying a variable to base the VariableObject off
   ///     of.
   ///
   /// \param[in] use_dynamic
   ///     Whether the correct dynamic type of an object pointer should be
   ///     determined before creating the object, or if the static type is
   ///     sufficient.  One of the DynamicValueType enumerated values.
   ///
   /// \param[in] options
   ///     An unsigned integer of flags, values from
   ///     StackFrame::ExpressionPathOption
   ///     enum.
   /// \param[in] var_sp
   ///     A VariableSP that will be set to the variable described in the
   ///     var_expr path.
   ///
   /// \param[in] error
   ///     Record any errors encountered while evaluating var_expr.
   ///
   /// \return
   ///     A shared pointer to the ValueObject described by var_expr.
   lldb::ValueObjectSP GetValueForVariableExpressionPath(
       llvm::StringRef var_expr, lldb::DynamicValueType use_dynamic,
       uint32_t options, lldb::VariableSP &var_sp, Status &error);

   /// Determine whether this StackFrame has debug information available or not.
   ///
   /// \return
   ///    true if debug information is available for this frame (function,
   ///    compilation unit, block, etc.)
   bool HasDebugInformation();

   /// Return the disassembly for the instructions of this StackFrame's
   /// function as a single C string.
   ///
   /// \return
   ///    C string with the assembly instructions for this function.
   const char *Disassemble();

   /// Print a description for this frame using the frame-format formatter
   /// settings.
   ///
   /// \param [in] strm
   ///   The Stream to print the description to.
   ///
   /// \param [in] show_unique
   ///   Whether to print the function arguments or not for backtrace unique.
   ///
   /// \param [in] frame_marker
   ///   Optional string that will be prepended to the frame output description.
   void DumpUsingSettingsFormat(Stream *strm, bool show_unique = false,
                                const char *frame_marker = nullptr);

   /// Print a description for this frame using a default format.
   ///
   /// \param [in] strm
   ///   The Stream to print the description to.
   ///
   /// \param [in] show_frame_index
   ///   Whether to print the frame number or not.
   ///
   /// \param [in] show_fullpaths
   ///   Whether to print the full source paths or just the file base name.
   void Dump(Stream *strm, bool show_frame_index, bool show_fullpaths);

   /// Print a description of this stack frame and/or the source
   /// context/assembly for this stack frame.
   ///
   /// \param[in] strm
   ///   The Stream to send the output to.
   ///
   /// \param[in] show_frame_info
   ///   If true, print the frame info by calling DumpUsingSettingsFormat().
   ///
   /// \param[in] show_source
   ///   If true, print source or disassembly as per the user's settings.
   ///
   /// \param[in] show_unique
   ///   If true, print using backtrace unique style, without function
   ///            arguments as per the user's settings.
   ///
   /// \param[in] frame_marker
   ///   Passed to DumpUsingSettingsFormat() for the frame info printing.
   ///
   /// \return
   ///   Returns true if successful.
   bool GetStatus(Stream &strm, bool show_frame_info, bool show_source,
                  bool show_unique = false, const char *frame_marker = nullptr);

   /// Query whether this frame is a concrete frame on the call stack, or if it
   /// is an inlined frame derived from the debug information and presented by
   /// the debugger.
   ///
   /// \return
   ///   true if this is an inlined frame.
   bool IsInlined();

   /// Query whether this frame is part of a historical backtrace.
   bool IsHistorical() const;

   /// Query whether this frame is artificial (e.g a synthesized result of
   /// inferring missing tail call frames from a backtrace). Artificial frames
   /// may have limited support for inspecting variables.
   bool IsArtificial() const;

   /// Query this frame to find what frame it is in this Thread's
   /// StackFrameList.
   ///
   /// \return
   ///   StackFrame index 0 indicates the currently-executing function.  Inline
   ///   frames are included in this frame index count.
   uint32_t GetFrameIndex() const;

   /// Set this frame's synthetic frame index.
   void SetFrameIndex(uint32_t index) { m_frame_index = index; }

   /// Query this frame to find what frame it is in this Thread's
   /// StackFrameList, not counting inlined frames.
   ///
   /// \return
   ///   StackFrame index 0 indicates the currently-executing function.  Inline
   ///   frames are not included in this frame index count; their concrete
   ///   frame index will be the same as the concrete frame that they are
   ///   derived from.
   uint32_t GetConcreteFrameIndex() const { return m_concrete_frame_index; }

   /// Create a ValueObject for a given Variable in this StackFrame.
   ///
   /// \params [in] variable_sp
   ///   The Variable to base this ValueObject on
   ///
   /// \params [in] use_dynamic
   ///     Whether the correct dynamic type of the variable should be
   ///     determined before creating the ValueObject, or if the static type
   ///     is sufficient.  One of the DynamicValueType enumerated values.
   ///
   /// \return
   ///     A ValueObject for this variable.
   lldb::ValueObjectSP
   GetValueObjectForFrameVariable(const lldb::VariableSP &variable_sp,
                                  lldb::DynamicValueType use_dynamic);

   /// Query this frame to determine what the default language should be when
   /// parsing expressions given the execution context.
   ///
   /// \return
   ///   The language of the frame if known, else lldb::eLanguageTypeUnknown.
   lldb::LanguageType GetLanguage();

   // similar to GetLanguage(), but is allowed to take a potentially incorrect
   // guess if exact information is not available
   lldb::LanguageType GuessLanguage();

   /// Attempt to econstruct the ValueObject for a given raw address touched by
   /// the current instruction.  The ExpressionPath should indicate how to get
   /// to this value using "frame variable."
   ///
   /// \params [in] addr
   ///   The raw address.
   ///
   /// \return
   ///   The ValueObject if found.  If valid, it has a valid ExpressionPath.
   lldb::ValueObjectSP GuessValueForAddress(lldb::addr_t addr);

   /// Attempt to reconstruct the ValueObject for the address contained in a
   /// given register plus an offset.  The ExpressionPath should indicate how
   /// to get to this value using "frame variable."
   ///
   /// \params [in] reg
   ///   The name of the register.
   ///
   /// \params [in] offset
   ///   The offset from the register.  Particularly important for sp...
   ///
   /// \return
   ///   The ValueObject if found.  If valid, it has a valid ExpressionPath.
   lldb::ValueObjectSP GuessValueForRegisterAndOffset(ConstString reg,
                                                      int64_t offset);

   /// Attempt to reconstruct the ValueObject for a variable with a given \a name
   /// from within the current StackFrame, within the current block. The search
   /// for the variable starts in the deepest block corresponding to the current
   /// PC in the stack frame and traverse through all parent blocks stopping at
   /// inlined function boundaries.
   ///
   /// \params [in] name
   ///   The name of the variable.
   ///
   /// \return
   ///   The ValueObject if found.
   lldb::ValueObjectSP FindVariable(ConstString name);

   // 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;

   lldb::RecognizedStackFrameSP GetRecognizedFrame();

 protected:
   friend class StackFrameList;

   void SetSymbolContextScope(SymbolContextScope *symbol_scope);

   void UpdateCurrentFrameFromPreviousFrame(StackFrame &prev_frame);

   void UpdatePreviousFrameFromCurrentFrame(StackFrame &curr_frame);

   bool HasCachedData() const;

 private:
   // For StackFrame only
   lldb::ThreadWP m_thread_wp;
   uint32_t m_frame_index;
   uint32_t m_concrete_frame_index;
   lldb::RegisterContextSP m_reg_context_sp;
   StackID m_id;
   Address m_frame_code_addr; // The frame code address (might not be the same as
                              // the actual PC for inlined frames) as a
                              // section/offset address
   SymbolContext m_sc;
   Flags m_flags;
   Scalar m_frame_base;
   Status m_frame_base_error;
   bool m_cfa_is_valid; // Does this frame have a CFA?  Different from CFA ==
                        // LLDB_INVALID_ADDRESS
   Kind m_stack_frame_kind;

   // Whether this frame behaves like the zeroth frame, in the sense
   // that its pc value might not immediately follow a call (and thus might
   // be the first address of its function). True for actual frame zero as
   // well as any other frame with the same trait.
   bool m_behaves_like_zeroth_frame;
   lldb::VariableListSP m_variable_list_sp;
   ValueObjectList m_variable_list_value_objects; // Value objects for each
                                                  // variable in
                                                  // m_variable_list_sp
   lldb::RecognizedStackFrameSP m_recognized_frame_sp;
   StreamString m_disassembly;
   std::recursive_mutex m_mutex;

   StackFrame(const StackFrame &) = delete;
   const StackFrame &operator=(const StackFrame &) = delete;
 };

 } // namespace lldb_private

 #endif // LLDB_TARGET_STACKFRAME_H
	//===-- StackFrame.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_STACKFRAME_H
	#define LLDB_TARGET_STACKFRAME_H

	#include <memory>
	#include <mutex>

	#include "lldb/Utility/Flags.h"

	#include "lldb/Core/ValueObjectList.h"
	#include "lldb/Symbol/SymbolContext.h"
	#include "lldb/Target/ExecutionContextScope.h"
	#include "lldb/Target/StackID.h"
	#include "lldb/Utility/Scalar.h"
	#include "lldb/Utility/Status.h"
	#include "lldb/Utility/StreamString.h"
	#include "lldb/Utility/UserID.h"

	namespace lldb_private {

	/// \class StackFrame StackFrame.h "lldb/Target/StackFrame.h"
	///
	/// This base class provides an interface to stack frames.
	///
	/// StackFrames may have a Canonical Frame Address (CFA) or not.
	/// A frame may have a plain pc value or it may indicate a specific point in
	/// the debug session so the correct section load list is used for
	/// symbolication.
	///
	/// Local variables may be available, or not. A register context may be
	/// available, or not.

	class StackFrame : public ExecutionContextScope,
	public std::enable_shared_from_this<StackFrame> {
	public:
	enum ExpressionPathOption {
	eExpressionPathOptionCheckPtrVsMember = (1u << 0),
	eExpressionPathOptionsNoFragileObjcIvar = (1u << 1),
	eExpressionPathOptionsNoSyntheticChildren = (1u << 2),
	eExpressionPathOptionsNoSyntheticArrayRange = (1u << 3),
	eExpressionPathOptionsAllowDirectIVarAccess = (1u << 4),
	eExpressionPathOptionsInspectAnonymousUnions = (1u << 5)
	};

	enum class Kind {
	/// A regular stack frame with access to registers and local variables.
	Regular,

	/// A historical stack frame -- possibly without CFA or registers or
	/// local variables.
	History,

	/// An artificial stack frame (e.g. a synthesized result of inferring
	/// missing tail call frames from a backtrace) with limited support for
	/// local variables.
	Artificial
	};

	/// Construct a StackFrame object without supplying a RegisterContextSP.
	///
	/// This is the one constructor that doesn't take a RegisterContext
	/// parameter. This ctor may be called when creating a history StackFrame;
	/// these are used if we've collected a stack trace of pc addresses at some
	/// point in the past. We may only have pc values. We may have a CFA,
	/// or more likely, we won't.
	///
	/// \param [in] thread_sp
	/// The Thread that this frame belongs to.
	///
	/// \param [in] frame_idx
	/// This StackFrame's frame index number in the Thread. If inlined stack
	/// frames are being created, this may differ from the concrete_frame_idx
	/// which is the frame index without any inlined stack frames.
	///
	/// \param [in] concrete_frame_idx
	/// The StackFrame's frame index number in the Thread without any inlined
	/// stack frames being included in the index.
	///
	/// \param [in] cfa
	/// The Canonical Frame Address (this terminology from DWARF) for this
	/// stack frame. The CFA for a stack frame does not change over the
	/// span of the stack frame's existence. It is often the value of the
	/// caller's stack pointer before the call instruction into this frame's
	/// function. It is usually not the same as the frame pointer register's
	/// value.
	///
	/// \param [in] cfa_is_valid
	/// A history stack frame may not have a CFA value collected. We want to
	/// distinguish between "no CFA available" and a CFA of
	/// LLDB_INVALID_ADDRESS.
	///
	/// \param [in] pc
	/// The current pc value of this stack frame.
	///
	/// \param [in] sc_ptr
	/// Optionally seed the StackFrame with the SymbolContext information that
	/// has
	/// already been discovered.
	StackFrame(const lldb::ThreadSP &thread_sp, lldb::user_id_t frame_idx,
	lldb::user_id_t concrete_frame_idx, lldb::addr_t cfa,
	bool cfa_is_valid, lldb::addr_t pc, Kind frame_kind,
	bool behaves_like_zeroth_frame, const SymbolContext *sc_ptr);

	StackFrame(const lldb::ThreadSP &thread_sp, lldb::user_id_t frame_idx,
	lldb::user_id_t concrete_frame_idx,
	const lldb::RegisterContextSP &reg_context_sp, lldb::addr_t cfa,
	lldb::addr_t pc, bool behaves_like_zeroth_frame,
	const SymbolContext *sc_ptr);

	StackFrame(const lldb::ThreadSP &thread_sp, lldb::user_id_t frame_idx,
	lldb::user_id_t concrete_frame_idx,
	const lldb::RegisterContextSP &reg_context_sp, lldb::addr_t cfa,
	const Address &pc, bool behaves_like_zeroth_frame,
	const SymbolContext *sc_ptr);

	~StackFrame() override;

	lldb::ThreadSP GetThread() const { return m_thread_wp.lock(); }

	StackID &GetStackID();

	/// Get an Address for the current pc value in this StackFrame.
	///
	/// May not be the same as the actual PC value for inlined stack frames.
	///
	/// \return
	/// The Address object set to the current PC value.
	const Address &GetFrameCodeAddress();

	/// Get the current code Address suitable for symbolication,
	/// may not be the same as GetFrameCodeAddress().
	///
	/// For a frame in the middle of the stack, the return-pc is the
	/// current code address, but for symbolication purposes the
	/// return address after a noreturn call may point to the next
	/// function, a DWARF location list entry that is a completely
	/// different code path, or the wrong source line.
	///
	/// The address returned should be used for symbolication (source line,
	/// block, function, DWARF location entry selection) but should NOT
	/// be shown to the user. It may not point to an actual instruction
	/// boundary.
	///
	/// \return
	/// The Address object set to the current PC value.
	Address GetFrameCodeAddressForSymbolication();

	/// Change the pc value for a given thread.
	///
	/// Change the current pc value for the frame on this thread.
	///
	/// \param[in] pc
	/// The load address that the pc will be set to.
	///
	/// \return
	/// true if the pc was changed. false if this failed -- possibly
	/// because this frame is not a live StackFrame.
	bool ChangePC(lldb::addr_t pc);

	/// Provide a SymbolContext for this StackFrame's current pc value.
	///
	/// The StackFrame maintains this SymbolContext and adds additional
	/// information to it on an as-needed basis. This helps to avoid different
	/// functions looking up symbolic information for a given pc value multiple
	/// times.
	///
	/// \params [in] resolve_scope
	/// Flags from the SymbolContextItem enumerated type which specify what
	/// type of symbol context is needed by this caller.
	///
	/// \return
	/// A SymbolContext reference which includes the types of information
	/// requested by resolve_scope, if they are available.
	const SymbolContext &GetSymbolContext(lldb::SymbolContextItem resolve_scope);

	/// Return the Canonical Frame Address (DWARF term) for this frame.
	///
	/// The CFA is typically the value of the stack pointer register before the
	/// call invocation is made. It will not change during the lifetime of a
	/// stack frame. It is often not the same thing as the frame pointer
	/// register value.
	///
	/// Live StackFrames will always have a CFA but other types of frames may
	/// not be able to supply one.
	///
	/// \param [out] value
	/// The address of the CFA for this frame, if available.
	///
	/// \param [out] error_ptr
	/// If there is an error determining the CFA address, this may contain a
	/// string explaining the failure.
	///
	/// \return
	/// Returns true if the CFA value was successfully set in value. Some
	/// frames may be unable to provide this value; they will return false.
	bool GetFrameBaseValue(Scalar &value, Status *error_ptr);

	/// Get the DWARFExpression corresponding to the Canonical Frame Address.
	///
	/// Often a register (bp), but sometimes a register + offset.
	///
	/// \param [out] error_ptr
	/// If there is an error determining the CFA address, this may contain a
	/// string explaining the failure.
	///
	/// \return
	/// Returns the corresponding DWARF expression, or NULL.
	DWARFExpression GetFrameBaseExpression(Status error_ptr);

	/// Get the current lexical scope block for this StackFrame, if possible.
	///
	/// If debug information is available for this stack frame, return a pointer
	/// to the innermost lexical Block that the frame is currently executing.
	///
	/// \return
	/// A pointer to the current Block. nullptr is returned if this can
	/// not be provided.
	Block *GetFrameBlock();

	/// Get the RegisterContext for this frame, if possible.
	///
	/// Returns a shared pointer to the RegisterContext for this stack frame.
	/// Only a live StackFrame object will be able to return a RegisterContext -
	/// callers must be prepared for an empty shared pointer being returned.
	///
	/// Even a live StackFrame RegisterContext may not be able to provide all
	/// registers. Only the currently executing frame (frame 0) can reliably
	/// provide every register in the register context.
	///
	/// \return
	/// The RegisterContext shared point for this frame.
	lldb::RegisterContextSP GetRegisterContext();

	const lldb::RegisterContextSP &GetRegisterContextSP() const {
	return m_reg_context_sp;
	}

	/// Retrieve the list of variables that are in scope at this StackFrame's
	/// pc.
	///
	/// A frame that is not live may return an empty VariableList for a given
	/// pc value even though variables would be available at this point if it
	/// were a live stack frame.
	///
	/// \param[in] get_file_globals
	/// Whether to also retrieve compilation-unit scoped variables
	/// that are visible to the entire compilation unit (e.g. file
	/// static in C, globals that are homed in this CU).
	///
	/// \return
	/// A pointer to a list of variables.
	VariableList *GetVariableList(bool get_file_globals);

	/// Retrieve the list of variables that are in scope at this StackFrame's
	/// pc.
	///
	/// A frame that is not live may return an empty VariableListSP for a
	/// given pc value even though variables would be available at this point if
	/// it were a live stack frame.
	///
	/// \param[in] get_file_globals
	/// Whether to also retrieve compilation-unit scoped variables
	/// that are visible to the entire compilation unit (e.g. file
	/// static in C, globals that are homed in this CU).
	///
	/// \return
	/// A pointer to a list of variables.
	lldb::VariableListSP
	GetInScopeVariableList(bool get_file_globals,
	bool must_have_valid_location = false);

	/// Create a ValueObject for a variable name / pathname, possibly including
	/// simple dereference/child selection syntax.
	///
	/// \param[in] var_expr
	/// The string specifying a variable to base the VariableObject off
	/// of.
	///
	/// \param[in] use_dynamic
	/// Whether the correct dynamic type of an object pointer should be
	/// determined before creating the object, or if the static type is
	/// sufficient. One of the DynamicValueType enumerated values.
	///
	/// \param[in] options
	/// An unsigned integer of flags, values from
	/// StackFrame::ExpressionPathOption
	/// enum.
	/// \param[in] var_sp
	/// A VariableSP that will be set to the variable described in the
	/// var_expr path.
	///
	/// \param[in] error
	/// Record any errors encountered while evaluating var_expr.
	///
	/// \return
	/// A shared pointer to the ValueObject described by var_expr.
	lldb::ValueObjectSP GetValueForVariableExpressionPath(
	llvm::StringRef var_expr, lldb::DynamicValueType use_dynamic,
	uint32_t options, lldb::VariableSP &var_sp, Status &error);

	/// Determine whether this StackFrame has debug information available or not.
	///
	/// \return
	/// true if debug information is available for this frame (function,
	/// compilation unit, block, etc.)
	bool HasDebugInformation();

	/// Return the disassembly for the instructions of this StackFrame's
	/// function as a single C string.
	///
	/// \return
	/// C string with the assembly instructions for this function.
	const char *Disassemble();

	/// Print a description for this frame using the frame-format formatter
	/// settings.
	///
	/// \param [in] strm
	/// The Stream to print the description to.
	///
	/// \param [in] show_unique
	/// Whether to print the function arguments or not for backtrace unique.
	///
	/// \param [in] frame_marker
	/// Optional string that will be prepended to the frame output description.
	void DumpUsingSettingsFormat(Stream *strm, bool show_unique = false,
	const char *frame_marker = nullptr);

	/// Print a description for this frame using a default format.
	///
	/// \param [in] strm
	/// The Stream to print the description to.
	///
	/// \param [in] show_frame_index
	/// Whether to print the frame number or not.
	///
	/// \param [in] show_fullpaths
	/// Whether to print the full source paths or just the file base name.
	void Dump(Stream *strm, bool show_frame_index, bool show_fullpaths);

	/// Print a description of this stack frame and/or the source
	/// context/assembly for this stack frame.
	///
	/// \param[in] strm
	/// The Stream to send the output to.
	///
	/// \param[in] show_frame_info
	/// If true, print the frame info by calling DumpUsingSettingsFormat().
	///
	/// \param[in] show_source
	/// If true, print source or disassembly as per the user's settings.
	///
	/// \param[in] show_unique
	/// If true, print using backtrace unique style, without function
	/// arguments as per the user's settings.
	///
	/// \param[in] frame_marker
	/// Passed to DumpUsingSettingsFormat() for the frame info printing.
	///
	/// \return
	/// Returns true if successful.
	bool GetStatus(Stream &strm, bool show_frame_info, bool show_source,
	bool show_unique = false, const char *frame_marker = nullptr);

	/// Query whether this frame is a concrete frame on the call stack, or if it
	/// is an inlined frame derived from the debug information and presented by
	/// the debugger.
	///
	/// \return
	/// true if this is an inlined frame.
	bool IsInlined();

	/// Query whether this frame is part of a historical backtrace.
	bool IsHistorical() const;

	/// Query whether this frame is artificial (e.g a synthesized result of
	/// inferring missing tail call frames from a backtrace). Artificial frames
	/// may have limited support for inspecting variables.
	bool IsArtificial() const;

	/// Query this frame to find what frame it is in this Thread's
	/// StackFrameList.
	///
	/// \return
	/// StackFrame index 0 indicates the currently-executing function. Inline
	/// frames are included in this frame index count.
	uint32_t GetFrameIndex() const;

	/// Set this frame's synthetic frame index.
	void SetFrameIndex(uint32_t index) { m_frame_index = index; }

	/// Query this frame to find what frame it is in this Thread's
	/// StackFrameList, not counting inlined frames.
	///
	/// \return
	/// StackFrame index 0 indicates the currently-executing function. Inline
	/// frames are not included in this frame index count; their concrete
	/// frame index will be the same as the concrete frame that they are
	/// derived from.
	uint32_t GetConcreteFrameIndex() const { return m_concrete_frame_index; }

	/// Create a ValueObject for a given Variable in this StackFrame.
	///
	/// \params [in] variable_sp
	/// The Variable to base this ValueObject on
	///
	/// \params [in] use_dynamic
	/// Whether the correct dynamic type of the variable should be
	/// determined before creating the ValueObject, or if the static type
	/// is sufficient. One of the DynamicValueType enumerated values.
	///
	/// \return
	/// A ValueObject for this variable.
	lldb::ValueObjectSP
	GetValueObjectForFrameVariable(const lldb::VariableSP &variable_sp,
	lldb::DynamicValueType use_dynamic);

	/// Query this frame to determine what the default language should be when
	/// parsing expressions given the execution context.
	///
	/// \return
	/// The language of the frame if known, else lldb::eLanguageTypeUnknown.
	lldb::LanguageType GetLanguage();

	// similar to GetLanguage(), but is allowed to take a potentially incorrect
	// guess if exact information is not available
	lldb::LanguageType GuessLanguage();

	/// Attempt to econstruct the ValueObject for a given raw address touched by
	/// the current instruction. The ExpressionPath should indicate how to get
	/// to this value using "frame variable."
	///
	/// \params [in] addr
	/// The raw address.
	///
	/// \return
	/// The ValueObject if found. If valid, it has a valid ExpressionPath.
	lldb::ValueObjectSP GuessValueForAddress(lldb::addr_t addr);

	/// Attempt to reconstruct the ValueObject for the address contained in a
	/// given register plus an offset. The ExpressionPath should indicate how
	/// to get to this value using "frame variable."
	///
	/// \params [in] reg
	/// The name of the register.
	///
	/// \params [in] offset
	/// The offset from the register. Particularly important for sp...
	///
	/// \return
	/// The ValueObject if found. If valid, it has a valid ExpressionPath.
	lldb::ValueObjectSP GuessValueForRegisterAndOffset(ConstString reg,
	int64_t offset);

	/// Attempt to reconstruct the ValueObject for a variable with a given \a name
	/// from within the current StackFrame, within the current block. The search
	/// for the variable starts in the deepest block corresponding to the current
	/// PC in the stack frame and traverse through all parent blocks stopping at
	/// inlined function boundaries.
	///
	/// \params [in] name
	/// The name of the variable.
	///
	/// \return
	/// The ValueObject if found.
	lldb::ValueObjectSP FindVariable(ConstString name);

	// 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;

	lldb::RecognizedStackFrameSP GetRecognizedFrame();

	protected:
	friend class StackFrameList;

	void SetSymbolContextScope(SymbolContextScope *symbol_scope);

	void UpdateCurrentFrameFromPreviousFrame(StackFrame &prev_frame);

	void UpdatePreviousFrameFromCurrentFrame(StackFrame &curr_frame);

	bool HasCachedData() const;

	private:
	// For StackFrame only
	lldb::ThreadWP m_thread_wp;
	uint32_t m_frame_index;
	uint32_t m_concrete_frame_index;
	lldb::RegisterContextSP m_reg_context_sp;
	StackID m_id;
	Address m_frame_code_addr; // The frame code address (might not be the same as
	// the actual PC for inlined frames) as a
	// section/offset address
	SymbolContext m_sc;
	Flags m_flags;
	Scalar m_frame_base;
	Status m_frame_base_error;
	bool m_cfa_is_valid; // Does this frame have a CFA? Different from CFA ==
	// LLDB_INVALID_ADDRESS
	Kind m_stack_frame_kind;

	// Whether this frame behaves like the zeroth frame, in the sense
	// that its pc value might not immediately follow a call (and thus might
	// be the first address of its function). True for actual frame zero as
	// well as any other frame with the same trait.
	bool m_behaves_like_zeroth_frame;
	lldb::VariableListSP m_variable_list_sp;
	ValueObjectList m_variable_list_value_objects; // Value objects for each
	// variable in
	// m_variable_list_sp
	lldb::RecognizedStackFrameSP m_recognized_frame_sp;
	StreamString m_disassembly;
	std::recursive_mutex m_mutex;

	StackFrame(const StackFrame &) = delete;
	const StackFrame &operator=(const StackFrame &) = delete;
	};

	} // namespace lldb_private

	#endif // LLDB_TARGET_STACKFRAME_H