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

 //===-- RegisterContextUnwind.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_REGISTERCONTEXTUNWIND_H
 #define LLDB_TARGET_REGISTERCONTEXTUNWIND_H

 #include <vector>

 #include "lldb/Symbol/SymbolContext.h"
 #include "lldb/Symbol/UnwindPlan.h"
 #include "lldb/Target/RegisterContext.h"
 #include "lldb/Target/RegisterNumber.h"
 #include "lldb/Target/UnwindLLDB.h"
 #include "lldb/lldb-private.h"

 namespace lldb_private {

 class UnwindLLDB;

 class RegisterContextUnwind : public lldb_private::RegisterContext {
 public:
   typedef std::shared_ptr<RegisterContextUnwind> SharedPtr;

   RegisterContextUnwind(lldb_private::Thread &thread,
                         const SharedPtr &next_frame,
                         lldb_private::SymbolContext &sym_ctx,
                         uint32_t frame_number,
                         lldb_private::UnwindLLDB &unwind_lldb);

   ~RegisterContextUnwind() override = default;

   void InvalidateAllRegisters() override;

   size_t GetRegisterCount() override;

   const lldb_private::RegisterInfo *GetRegisterInfoAtIndex(size_t reg) override;

   size_t GetRegisterSetCount() override;

   const lldb_private::RegisterSet *GetRegisterSet(size_t reg_set) override;

   bool ReadRegister(const lldb_private::RegisterInfo *reg_info,
                     lldb_private::RegisterValue &value) override;

   bool WriteRegister(const lldb_private::RegisterInfo *reg_info,
                      const lldb_private::RegisterValue &value) override;

   bool ReadAllRegisterValues(lldb::DataBufferSP &data_sp) override;

   bool WriteAllRegisterValues(const lldb::DataBufferSP &data_sp) override;

   uint32_t ConvertRegisterKindToRegisterNumber(lldb::RegisterKind kind,
                                                uint32_t num) override;

   bool IsValid() const;

   bool IsTrapHandlerFrame() const;

   bool GetCFA(lldb::addr_t &cfa);

   bool GetStartPC(lldb::addr_t &start_pc);

   bool ReadPC(lldb::addr_t &start_pc);

   // Indicates whether this frame *behaves* like frame zero -- the currently
   // executing frame -- or not.  This can be true in the middle of the stack
   // above asynchronous trap handlers (sigtramp) for instance.
   bool BehavesLikeZerothFrame() const override;

 private:
   enum FrameType {
     eNormalFrame,
     eTrapHandlerFrame,
     eDebuggerFrame, // a debugger inferior function call frame; we get caller's
                     // registers from debugger
     eSkipFrame,     // The unwind resulted in a bogus frame but may get back on
                     // track so we don't want to give up yet
     eNotAValidFrame // this frame is invalid for some reason - most likely it is
                     // past the top (end) of the stack
   };

   // UnwindLLDB needs to pass around references to RegisterLocations
   friend class UnwindLLDB;

   // Returns true if we have an unwind loop -- the same stack frame unwinding
   // multiple times.
   bool CheckIfLoopingStack();

   // Indicates whether this frame is frame zero -- the currently
   // executing frame -- or not.
   bool IsFrameZero() const;

   void InitializeZerothFrame();

   void InitializeNonZerothFrame();

   SharedPtr GetNextFrame() const;

   SharedPtr GetPrevFrame() const;

   // A SkipFrame occurs when the unwind out of frame 0 didn't go right -- we've
   // got one bogus frame at frame #1.
   // There is a good chance we'll get back on track if we follow the frame
   // pointer chain (or whatever is appropriate
   // on this ABI) so we allow one invalid frame to be in the stack.  Ideally
   // we'll mark this frame specially at some
   // point and indicate to the user that the unwinder had a hiccup.  Often when
   // this happens we will miss a frame of
   // the program's actual stack in the unwind and we want to flag that for the
   // user somehow.
   bool IsSkipFrame() const;

   /// Determines if a SymbolContext is a trap handler or not
   ///
   /// Given a SymbolContext, determines if this is a trap handler function
   /// aka asynchronous signal handler.
   ///
   /// \return
   ///     Returns true if the SymbolContext is a trap handler.
   bool IsTrapHandlerSymbol(lldb_private::Process *process,
                            const lldb_private::SymbolContext &m_sym_ctx) const;

   /// Check if the given unwind plan indicates a signal trap handler, and
   /// update frame type and symbol context if so.
   void PropagateTrapHandlerFlagFromUnwindPlan(lldb::UnwindPlanSP unwind_plan);

   // Provide a location for where THIS function saved the CALLER's register
   // value
   // Or a frame "below" this one saved it, i.e. a function called by this one,
   // preserved a register that this
   // function didn't modify/use.
   //
   // The RegisterLocation type may be set to eRegisterNotAvailable -- this will
   // happen for a volatile register
   // being queried mid-stack.  Instead of floating frame 0's contents of that
   // register up the stack (which may
   // or may not be the value of that reg when the function was executing), we
   // won't return any value.
   //
   // If a non-volatile register (a "preserved" register) is requested mid-stack
   // and no frames "below" the requested
   // stack have saved the register anywhere, it is safe to assume that frame 0's
   // register values are still the same
   // as the requesting frame's.
   lldb_private::UnwindLLDB::RegisterSearchResult
   SavedLocationForRegister(uint32_t lldb_regnum,
                            lldb_private::UnwindLLDB::RegisterLocation &regloc);

   bool ReadRegisterValueFromRegisterLocation(
       lldb_private::UnwindLLDB::RegisterLocation regloc,
       const lldb_private::RegisterInfo *reg_info,
       lldb_private::RegisterValue &value);

   bool WriteRegisterValueToRegisterLocation(
       lldb_private::UnwindLLDB::RegisterLocation regloc,
       const lldb_private::RegisterInfo *reg_info,
       const lldb_private::RegisterValue &value);

   /// If the unwind has to the caller frame has failed, try something else
   ///
   /// If lldb is using an assembly language based UnwindPlan for a frame and
   /// the unwind to the caller frame fails, try falling back to a generic
   /// UnwindPlan (architecture default unwindplan) to see if that might work
   /// better.  This is mostly helping to work around problems where the
   /// assembly language inspection fails on hand-written assembly code.
   ///
   /// \return
   ///     Returns true if a fallback unwindplan was found & was installed.
   bool TryFallbackUnwindPlan();

   /// Switch to the fallback unwind plan unconditionally without any safety
   /// checks that it is providing better results than the normal unwind plan.
   ///
   /// The only time it is valid to call this method is if the full unwindplan is
   /// found to be fundamentally incorrect/impossible.
   ///
   /// Returns true if it was able to install the fallback unwind plan.
   bool ForceSwitchToFallbackUnwindPlan();

   // Get the contents of a general purpose (address-size) register for this
   // frame
   // (usually retrieved from the next frame)
   bool ReadGPRValue(lldb::RegisterKind register_kind, uint32_t regnum,
                     lldb::addr_t &value);

   bool ReadGPRValue(const RegisterNumber &reg_num, lldb::addr_t &value);

   // Get the Frame Address register for a given frame.
   bool ReadFrameAddress(lldb::RegisterKind register_kind,
                           UnwindPlan::Row::FAValue &fa, lldb::addr_t &address);

   lldb::UnwindPlanSP GetFastUnwindPlanForFrame();

   lldb::UnwindPlanSP GetFullUnwindPlanForFrame();

   void UnwindLogMsg(const char *fmt, ...) __attribute__((format(printf, 2, 3)));

   void UnwindLogMsgVerbose(const char *fmt, ...)
       __attribute__((format(printf, 2, 3)));

   bool IsUnwindPlanValidForCurrentPC(lldb::UnwindPlanSP unwind_plan_sp,
                                      int &valid_pc_offset);

   lldb::addr_t GetReturnAddressHint(int32_t plan_offset);

   lldb_private::Thread &m_thread;

   ///
   // The following tell us how to retrieve the CALLER's register values (ie the
   // "previous" frame, aka the frame above)
   // i.e. where THIS frame saved them
   ///

   lldb::UnwindPlanSP m_fast_unwind_plan_sp; // may be NULL
   lldb::UnwindPlanSP m_full_unwind_plan_sp;
   lldb::UnwindPlanSP m_fallback_unwind_plan_sp; // may be NULL

   bool m_all_registers_available; // Can we retrieve all regs or just
                                   // nonvolatile regs?
   int m_frame_type;               // enum FrameType

   lldb::addr_t m_cfa;
   lldb::addr_t m_afa;
   lldb_private::Address m_start_pc;
   lldb_private::Address m_current_pc;

   int m_current_offset; // how far into the function we've executed; -1 if
                         // unknown
                         // 0 if no instructions have been executed yet.

   // 0 if no instructions have been executed yet.
   // On architectures where the return address on the stack points
   // to the instruction after the CALL, this value will have 1
   // subtracted from it.  Else a function that ends in a CALL will
   // have an offset pointing into the next function's address range.
   // m_current_pc has the actual address of the "current" pc.
   int m_current_offset_backed_up_one; // how far into the function we've
                                       // executed; -1 if unknown

   bool m_behaves_like_zeroth_frame; // this frame behaves like frame zero

   lldb_private::SymbolContext &m_sym_ctx;
   bool m_sym_ctx_valid; // if ResolveSymbolContextForAddress fails, don't try to
                         // use m_sym_ctx

   uint32_t m_frame_number; // What stack frame this RegisterContext is

   std::map<uint32_t, lldb_private::UnwindLLDB::RegisterLocation>
       m_registers; // where to find reg values for this frame

   lldb_private::UnwindLLDB &m_parent_unwind; // The UnwindLLDB that is creating
                                              // this RegisterContextUnwind

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

 } // namespace lldb_private

 #endif // LLDB_TARGET_REGISTERCONTEXTUNWIND_H
	//===-- RegisterContextUnwind.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_REGISTERCONTEXTUNWIND_H
	#define LLDB_TARGET_REGISTERCONTEXTUNWIND_H

	#include <vector>

	#include "lldb/Symbol/SymbolContext.h"
	#include "lldb/Symbol/UnwindPlan.h"
	#include "lldb/Target/RegisterContext.h"
	#include "lldb/Target/RegisterNumber.h"
	#include "lldb/Target/UnwindLLDB.h"
	#include "lldb/lldb-private.h"

	namespace lldb_private {

	class UnwindLLDB;

	class RegisterContextUnwind : public lldb_private::RegisterContext {
	public:
	typedef std::shared_ptr<RegisterContextUnwind> SharedPtr;

	RegisterContextUnwind(lldb_private::Thread &thread,
	const SharedPtr &next_frame,
	lldb_private::SymbolContext &sym_ctx,
	uint32_t frame_number,
	lldb_private::UnwindLLDB &unwind_lldb);

	~RegisterContextUnwind() override = default;

	void InvalidateAllRegisters() override;

	size_t GetRegisterCount() override;

	const lldb_private::RegisterInfo *GetRegisterInfoAtIndex(size_t reg) override;

	size_t GetRegisterSetCount() override;

	const lldb_private::RegisterSet *GetRegisterSet(size_t reg_set) override;

	bool ReadRegister(const lldb_private::RegisterInfo *reg_info,
	lldb_private::RegisterValue &value) override;

	bool WriteRegister(const lldb_private::RegisterInfo *reg_info,
	const lldb_private::RegisterValue &value) override;

	bool ReadAllRegisterValues(lldb::DataBufferSP &data_sp) override;

	bool WriteAllRegisterValues(const lldb::DataBufferSP &data_sp) override;

	uint32_t ConvertRegisterKindToRegisterNumber(lldb::RegisterKind kind,
	uint32_t num) override;

	bool IsValid() const;

	bool IsTrapHandlerFrame() const;

	bool GetCFA(lldb::addr_t &cfa);

	bool GetStartPC(lldb::addr_t &start_pc);

	bool ReadPC(lldb::addr_t &start_pc);

	// Indicates whether this frame behaves like frame zero -- the currently
	// executing frame -- or not. This can be true in the middle of the stack
	// above asynchronous trap handlers (sigtramp) for instance.
	bool BehavesLikeZerothFrame() const override;

	private:
	enum FrameType {
	eNormalFrame,
	eTrapHandlerFrame,
	eDebuggerFrame, // a debugger inferior function call frame; we get caller's
	// registers from debugger
	eSkipFrame, // The unwind resulted in a bogus frame but may get back on
	// track so we don't want to give up yet
	eNotAValidFrame // this frame is invalid for some reason - most likely it is
	// past the top (end) of the stack
	};

	// UnwindLLDB needs to pass around references to RegisterLocations
	friend class UnwindLLDB;

	// Returns true if we have an unwind loop -- the same stack frame unwinding
	// multiple times.
	bool CheckIfLoopingStack();

	// Indicates whether this frame is frame zero -- the currently
	// executing frame -- or not.
	bool IsFrameZero() const;

	void InitializeZerothFrame();

	void InitializeNonZerothFrame();

	SharedPtr GetNextFrame() const;

	SharedPtr GetPrevFrame() const;

	// A SkipFrame occurs when the unwind out of frame 0 didn't go right -- we've
	// got one bogus frame at frame #1.
	// There is a good chance we'll get back on track if we follow the frame
	// pointer chain (or whatever is appropriate
	// on this ABI) so we allow one invalid frame to be in the stack. Ideally
	// we'll mark this frame specially at some
	// point and indicate to the user that the unwinder had a hiccup. Often when
	// this happens we will miss a frame of
	// the program's actual stack in the unwind and we want to flag that for the
	// user somehow.
	bool IsSkipFrame() const;

	/// Determines if a SymbolContext is a trap handler or not
	///
	/// Given a SymbolContext, determines if this is a trap handler function
	/// aka asynchronous signal handler.
	///
	/// \return
	/// Returns true if the SymbolContext is a trap handler.
	bool IsTrapHandlerSymbol(lldb_private::Process *process,
	const lldb_private::SymbolContext &m_sym_ctx) const;

	/// Check if the given unwind plan indicates a signal trap handler, and
	/// update frame type and symbol context if so.
	void PropagateTrapHandlerFlagFromUnwindPlan(lldb::UnwindPlanSP unwind_plan);

	// Provide a location for where THIS function saved the CALLER's register
	// value
	// Or a frame "below" this one saved it, i.e. a function called by this one,
	// preserved a register that this
	// function didn't modify/use.
	//
	// The RegisterLocation type may be set to eRegisterNotAvailable -- this will
	// happen for a volatile register
	// being queried mid-stack. Instead of floating frame 0's contents of that
	// register up the stack (which may
	// or may not be the value of that reg when the function was executing), we
	// won't return any value.
	//
	// If a non-volatile register (a "preserved" register) is requested mid-stack
	// and no frames "below" the requested
	// stack have saved the register anywhere, it is safe to assume that frame 0's
	// register values are still the same
	// as the requesting frame's.
	lldb_private::UnwindLLDB::RegisterSearchResult
	SavedLocationForRegister(uint32_t lldb_regnum,
	lldb_private::UnwindLLDB::RegisterLocation &regloc);

	bool ReadRegisterValueFromRegisterLocation(
	lldb_private::UnwindLLDB::RegisterLocation regloc,
	const lldb_private::RegisterInfo *reg_info,
	lldb_private::RegisterValue &value);

	bool WriteRegisterValueToRegisterLocation(
	lldb_private::UnwindLLDB::RegisterLocation regloc,
	const lldb_private::RegisterInfo *reg_info,
	const lldb_private::RegisterValue &value);

	/// If the unwind has to the caller frame has failed, try something else
	///
	/// If lldb is using an assembly language based UnwindPlan for a frame and
	/// the unwind to the caller frame fails, try falling back to a generic
	/// UnwindPlan (architecture default unwindplan) to see if that might work
	/// better. This is mostly helping to work around problems where the
	/// assembly language inspection fails on hand-written assembly code.
	///
	/// \return
	/// Returns true if a fallback unwindplan was found & was installed.
	bool TryFallbackUnwindPlan();

	/// Switch to the fallback unwind plan unconditionally without any safety
	/// checks that it is providing better results than the normal unwind plan.
	///
	/// The only time it is valid to call this method is if the full unwindplan is
	/// found to be fundamentally incorrect/impossible.
	///
	/// Returns true if it was able to install the fallback unwind plan.
	bool ForceSwitchToFallbackUnwindPlan();

	// Get the contents of a general purpose (address-size) register for this
	// frame
	// (usually retrieved from the next frame)
	bool ReadGPRValue(lldb::RegisterKind register_kind, uint32_t regnum,
	lldb::addr_t &value);

	bool ReadGPRValue(const RegisterNumber &reg_num, lldb::addr_t &value);

	// Get the Frame Address register for a given frame.
	bool ReadFrameAddress(lldb::RegisterKind register_kind,
	UnwindPlan::Row::FAValue &fa, lldb::addr_t &address);

	lldb::UnwindPlanSP GetFastUnwindPlanForFrame();

	lldb::UnwindPlanSP GetFullUnwindPlanForFrame();

	void UnwindLogMsg(const char *fmt, ...) __attribute__((format(printf, 2, 3)));

	void UnwindLogMsgVerbose(const char *fmt, ...)
	__attribute__((format(printf, 2, 3)));

	bool IsUnwindPlanValidForCurrentPC(lldb::UnwindPlanSP unwind_plan_sp,
	int &valid_pc_offset);

	lldb::addr_t GetReturnAddressHint(int32_t plan_offset);

	lldb_private::Thread &m_thread;

	///
	// The following tell us how to retrieve the CALLER's register values (ie the
	// "previous" frame, aka the frame above)
	// i.e. where THIS frame saved them
	///

	lldb::UnwindPlanSP m_fast_unwind_plan_sp; // may be NULL
	lldb::UnwindPlanSP m_full_unwind_plan_sp;
	lldb::UnwindPlanSP m_fallback_unwind_plan_sp; // may be NULL

	bool m_all_registers_available; // Can we retrieve all regs or just
	// nonvolatile regs?
	int m_frame_type; // enum FrameType

	lldb::addr_t m_cfa;
	lldb::addr_t m_afa;
	lldb_private::Address m_start_pc;
	lldb_private::Address m_current_pc;

	int m_current_offset; // how far into the function we've executed; -1 if
	// unknown
	// 0 if no instructions have been executed yet.

	// 0 if no instructions have been executed yet.
	// On architectures where the return address on the stack points
	// to the instruction after the CALL, this value will have 1
	// subtracted from it. Else a function that ends in a CALL will
	// have an offset pointing into the next function's address range.
	// m_current_pc has the actual address of the "current" pc.
	int m_current_offset_backed_up_one; // how far into the function we've
	// executed; -1 if unknown

	bool m_behaves_like_zeroth_frame; // this frame behaves like frame zero

	lldb_private::SymbolContext &m_sym_ctx;
	bool m_sym_ctx_valid; // if ResolveSymbolContextForAddress fails, don't try to
	// use m_sym_ctx

	uint32_t m_frame_number; // What stack frame this RegisterContext is

	std::map<uint32_t, lldb_private::UnwindLLDB::RegisterLocation>
	m_registers; // where to find reg values for this frame

	lldb_private::UnwindLLDB &m_parent_unwind; // The UnwindLLDB that is creating
	// this RegisterContextUnwind

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

	} // namespace lldb_private

	#endif // LLDB_TARGET_REGISTERCONTEXTUNWIND_H