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

 //===-- RegisterContext.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_REGISTERCONTEXT_H
 #define LLDB_TARGET_REGISTERCONTEXT_H

 #include "lldb/Target/ExecutionContextScope.h"
 #include "lldb/lldb-private.h"

 namespace lldb_private {

 class RegisterContext : public std::enable_shared_from_this<RegisterContext>,
                         public ExecutionContextScope {
 public:
   // Constructors and Destructors
   RegisterContext(Thread &thread, uint32_t concrete_frame_idx);

   ~RegisterContext() override;

   void InvalidateIfNeeded(bool force);

   // Subclasses must override these functions
   virtual void InvalidateAllRegisters() = 0;

   virtual size_t GetRegisterCount() = 0;

   virtual const RegisterInfo *GetRegisterInfoAtIndex(size_t reg) = 0;

   // Detect the register size dynamically.
   uint32_t UpdateDynamicRegisterSize(const lldb_private::ArchSpec &arch,
                                      RegisterInfo *reg_info);

   virtual size_t GetRegisterSetCount() = 0;

   virtual const RegisterSet *GetRegisterSet(size_t reg_set) = 0;

   virtual lldb::ByteOrder GetByteOrder();

   virtual bool ReadRegister(const RegisterInfo *reg_info,
                             RegisterValue &reg_value) = 0;

   virtual bool WriteRegister(const RegisterInfo *reg_info,
                              const RegisterValue &reg_value) = 0;

   virtual bool ReadAllRegisterValues(lldb::DataBufferSP &data_sp) {
     return false;
   }

   virtual bool WriteAllRegisterValues(const lldb::DataBufferSP &data_sp) {
     return false;
   }

   // These two functions are used to implement "push" and "pop" of register
   // states.  They are used primarily for expression evaluation, where we need
   // to push a new state (storing the old one in data_sp) and then restoring
   // the original state by passing the data_sp we got from ReadAllRegisters to
   // WriteAllRegisterValues. ReadAllRegisters will do what is necessary to
   // return a coherent set of register values for this thread, which may mean
   // e.g. interrupting a thread that is sitting in a kernel trap.  That is a
   // somewhat disruptive operation, so these API's should only be used when
   // this behavior is needed.

   virtual bool
   ReadAllRegisterValues(lldb_private::RegisterCheckpoint &reg_checkpoint);

   virtual bool WriteAllRegisterValues(
       const lldb_private::RegisterCheckpoint &reg_checkpoint);

   bool CopyFromRegisterContext(lldb::RegisterContextSP context);

   /// Convert from a given register numbering scheme to the lldb register
   /// numbering scheme
   ///
   /// There may be multiple ways to enumerate the registers for a given
   /// architecture.  ABI references will specify one to be used with
   /// DWARF, the register numberings from process plugin, there may
   /// be a variation used for eh_frame unwind instructions (e.g. on Darwin),
   /// and so on.  Register 5 by itself is meaningless - RegisterKind
   /// enumeration tells you what context that number should be translated as.
   ///
   /// Inside lldb, register numbers are in the eRegisterKindLLDB scheme;
   /// arguments which take a register number should take one in that
   /// scheme.
   ///
   /// eRegisterKindGeneric is a special numbering scheme which gives us
   /// constant values for the pc, frame register, stack register, etc., for
   /// use within lldb.  They may not be defined for all architectures but
   /// it allows generic code to translate these common registers into the
   /// lldb numbering scheme.
   ///
   /// This method translates a given register kind + register number into
   /// the eRegisterKindLLDB register numbering.
   ///
   /// \param [in] kind
   ///     The register numbering scheme (RegisterKind) that the following
   ///     register number is in.
   ///
   /// \param [in] num
   ///     A register number in the 'kind' register numbering scheme.
   ///
   /// \return
   ///     The equivalent register number in the eRegisterKindLLDB
   ///     numbering scheme, if possible, else LLDB_INVALID_REGNUM.
   virtual uint32_t ConvertRegisterKindToRegisterNumber(lldb::RegisterKind kind,
                                                        uint32_t num);

   // Subclasses can override these functions if desired
   virtual uint32_t NumSupportedHardwareBreakpoints();

   virtual uint32_t SetHardwareBreakpoint(lldb::addr_t addr, size_t size);

   virtual bool ClearHardwareBreakpoint(uint32_t hw_idx);

   virtual uint32_t NumSupportedHardwareWatchpoints();

   virtual uint32_t SetHardwareWatchpoint(lldb::addr_t addr, size_t size,
                                          bool read, bool write);

   virtual bool ClearHardwareWatchpoint(uint32_t hw_index);

   virtual bool HardwareSingleStep(bool enable);

   virtual Status
   ReadRegisterValueFromMemory(const lldb_private::RegisterInfo *reg_info,
                               lldb::addr_t src_addr, uint32_t src_len,
                               RegisterValue &reg_value);

   virtual Status
   WriteRegisterValueToMemory(const lldb_private::RegisterInfo *reg_info,
                              lldb::addr_t dst_addr, uint32_t dst_len,
                              const RegisterValue &reg_value);

   // Subclasses should not override these
   virtual lldb::tid_t GetThreadID() const;

   virtual Thread &GetThread() { return m_thread; }

   const RegisterInfo *GetRegisterInfoByName(llvm::StringRef reg_name,
                                             uint32_t start_idx = 0);

   const RegisterInfo *GetRegisterInfo(lldb::RegisterKind reg_kind,
                                       uint32_t reg_num);

   uint64_t GetPC(uint64_t fail_value = LLDB_INVALID_ADDRESS);

   /// Get an address suitable for symbolication.
   /// When symbolicating -- computing line, block, function --
   /// for a function in the middle of the stack, using the return
   /// address can lead to unexpected results for the user.
   /// A function that ends in a tail-call may have another function
   /// as the "return" address, but it will never actually return.
   /// Or a noreturn call in the middle of a function is the end of
   /// a block of instructions, and a DWARF location list entry for
   /// the return address may be a very different code path with
   /// incorrect results when printing variables for this frame.
   ///
   /// At a source line view, the user expects the current-line indictation
   /// to point to the function call they're under, not the next source line.
   ///
   /// The return address (GetPC()) should always be shown to the user,
   /// but when computing context, keeping within the bounds of the
   /// call instruction is what the user expects to see.
   ///
   /// \param [out] address
   ///     An Address object that will be filled in, if a PC can be retrieved.
   ///
   /// \return
   ///     Returns true if the Address param was filled in.
   bool GetPCForSymbolication(Address &address);

   bool SetPC(uint64_t pc);

   bool SetPC(Address addr);

   uint64_t GetSP(uint64_t fail_value = LLDB_INVALID_ADDRESS);

   bool SetSP(uint64_t sp);

   uint64_t GetFP(uint64_t fail_value = LLDB_INVALID_ADDRESS);

   bool SetFP(uint64_t fp);

   const char *GetRegisterName(uint32_t reg);

   uint64_t GetReturnAddress(uint64_t fail_value = LLDB_INVALID_ADDRESS);

   uint64_t GetFlags(uint64_t fail_value = 0);

   uint64_t ReadRegisterAsUnsigned(uint32_t reg, uint64_t fail_value);

   uint64_t ReadRegisterAsUnsigned(const RegisterInfo *reg_info,
                                   uint64_t fail_value);

   bool WriteRegisterFromUnsigned(uint32_t reg, uint64_t uval);

   bool WriteRegisterFromUnsigned(const RegisterInfo *reg_info, uint64_t uval);

   bool ConvertBetweenRegisterKinds(lldb::RegisterKind source_rk,
                                    uint32_t source_regnum,
                                    lldb::RegisterKind target_rk,
                                    uint32_t &target_regnum);

   // 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;

   uint32_t GetStopID() const { return m_stop_id; }

   void SetStopID(uint32_t stop_id) { m_stop_id = stop_id; }

 protected:
   /// Indicates that this frame is currently executing code,
   /// that the PC value is not a return-pc but an actual executing
   /// instruction.  Some places in lldb will treat a return-pc
   /// value differently than the currently-executing-pc value,
   /// and this method can indicate if that should be done.
   /// The base class implementation only uses the frame index,
   /// but subclasses may have additional information that they
   /// can use to detect frames in this state, for instance a
   /// frame above a trap handler (sigtramp etc)..
   virtual bool BehavesLikeZerothFrame() const {
     return m_concrete_frame_idx == 0;
   }

   // Classes that inherit from RegisterContext can see and modify these
   Thread &m_thread; // The thread that this register context belongs to.
   uint32_t m_concrete_frame_idx; // The concrete frame index for this register
                                  // context
   uint32_t m_stop_id; // The stop ID that any data in this context is valid for
 private:
   // For RegisterContext only
   RegisterContext(const RegisterContext &) = delete;
   const RegisterContext &operator=(const RegisterContext &) = delete;
 };

 } // namespace lldb_private

 #endif // LLDB_TARGET_REGISTERCONTEXT_H
	//===-- RegisterContext.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_REGISTERCONTEXT_H
	#define LLDB_TARGET_REGISTERCONTEXT_H

	#include "lldb/Target/ExecutionContextScope.h"
	#include "lldb/lldb-private.h"

	namespace lldb_private {

	class RegisterContext : public std::enable_shared_from_this<RegisterContext>,
	public ExecutionContextScope {
	public:
	// Constructors and Destructors
	RegisterContext(Thread &thread, uint32_t concrete_frame_idx);

	~RegisterContext() override;

	void InvalidateIfNeeded(bool force);

	// Subclasses must override these functions
	virtual void InvalidateAllRegisters() = 0;

	virtual size_t GetRegisterCount() = 0;

	virtual const RegisterInfo *GetRegisterInfoAtIndex(size_t reg) = 0;

	// Detect the register size dynamically.
	uint32_t UpdateDynamicRegisterSize(const lldb_private::ArchSpec &arch,
	RegisterInfo *reg_info);

	virtual size_t GetRegisterSetCount() = 0;

	virtual const RegisterSet *GetRegisterSet(size_t reg_set) = 0;

	virtual lldb::ByteOrder GetByteOrder();

	virtual bool ReadRegister(const RegisterInfo *reg_info,
	RegisterValue &reg_value) = 0;

	virtual bool WriteRegister(const RegisterInfo *reg_info,
	const RegisterValue &reg_value) = 0;

	virtual bool ReadAllRegisterValues(lldb::DataBufferSP &data_sp) {
	return false;
	}

	virtual bool WriteAllRegisterValues(const lldb::DataBufferSP &data_sp) {
	return false;
	}

	// These two functions are used to implement "push" and "pop" of register
	// states. They are used primarily for expression evaluation, where we need
	// to push a new state (storing the old one in data_sp) and then restoring
	// the original state by passing the data_sp we got from ReadAllRegisters to
	// WriteAllRegisterValues. ReadAllRegisters will do what is necessary to
	// return a coherent set of register values for this thread, which may mean
	// e.g. interrupting a thread that is sitting in a kernel trap. That is a
	// somewhat disruptive operation, so these API's should only be used when
	// this behavior is needed.

	virtual bool
	ReadAllRegisterValues(lldb_private::RegisterCheckpoint &reg_checkpoint);

	virtual bool WriteAllRegisterValues(
	const lldb_private::RegisterCheckpoint &reg_checkpoint);

	bool CopyFromRegisterContext(lldb::RegisterContextSP context);

	/// Convert from a given register numbering scheme to the lldb register
	/// numbering scheme
	///
	/// There may be multiple ways to enumerate the registers for a given
	/// architecture. ABI references will specify one to be used with
	/// DWARF, the register numberings from process plugin, there may
	/// be a variation used for eh_frame unwind instructions (e.g. on Darwin),
	/// and so on. Register 5 by itself is meaningless - RegisterKind
	/// enumeration tells you what context that number should be translated as.
	///
	/// Inside lldb, register numbers are in the eRegisterKindLLDB scheme;
	/// arguments which take a register number should take one in that
	/// scheme.
	///
	/// eRegisterKindGeneric is a special numbering scheme which gives us
	/// constant values for the pc, frame register, stack register, etc., for
	/// use within lldb. They may not be defined for all architectures but
	/// it allows generic code to translate these common registers into the
	/// lldb numbering scheme.
	///
	/// This method translates a given register kind + register number into
	/// the eRegisterKindLLDB register numbering.
	///
	/// \param [in] kind
	/// The register numbering scheme (RegisterKind) that the following
	/// register number is in.
	///
	/// \param [in] num
	/// A register number in the 'kind' register numbering scheme.
	///
	/// \return
	/// The equivalent register number in the eRegisterKindLLDB
	/// numbering scheme, if possible, else LLDB_INVALID_REGNUM.
	virtual uint32_t ConvertRegisterKindToRegisterNumber(lldb::RegisterKind kind,
	uint32_t num);

	// Subclasses can override these functions if desired
	virtual uint32_t NumSupportedHardwareBreakpoints();

	virtual uint32_t SetHardwareBreakpoint(lldb::addr_t addr, size_t size);

	virtual bool ClearHardwareBreakpoint(uint32_t hw_idx);

	virtual uint32_t NumSupportedHardwareWatchpoints();

	virtual uint32_t SetHardwareWatchpoint(lldb::addr_t addr, size_t size,
	bool read, bool write);

	virtual bool ClearHardwareWatchpoint(uint32_t hw_index);

	virtual bool HardwareSingleStep(bool enable);

	virtual Status
	ReadRegisterValueFromMemory(const lldb_private::RegisterInfo *reg_info,
	lldb::addr_t src_addr, uint32_t src_len,
	RegisterValue &reg_value);

	virtual Status
	WriteRegisterValueToMemory(const lldb_private::RegisterInfo *reg_info,
	lldb::addr_t dst_addr, uint32_t dst_len,
	const RegisterValue &reg_value);

	// Subclasses should not override these
	virtual lldb::tid_t GetThreadID() const;

	virtual Thread &GetThread() { return m_thread; }

	const RegisterInfo *GetRegisterInfoByName(llvm::StringRef reg_name,
	uint32_t start_idx = 0);

	const RegisterInfo *GetRegisterInfo(lldb::RegisterKind reg_kind,
	uint32_t reg_num);

	uint64_t GetPC(uint64_t fail_value = LLDB_INVALID_ADDRESS);

	/// Get an address suitable for symbolication.
	/// When symbolicating -- computing line, block, function --
	/// for a function in the middle of the stack, using the return
	/// address can lead to unexpected results for the user.
	/// A function that ends in a tail-call may have another function
	/// as the "return" address, but it will never actually return.
	/// Or a noreturn call in the middle of a function is the end of
	/// a block of instructions, and a DWARF location list entry for
	/// the return address may be a very different code path with
	/// incorrect results when printing variables for this frame.
	///
	/// At a source line view, the user expects the current-line indictation
	/// to point to the function call they're under, not the next source line.
	///
	/// The return address (GetPC()) should always be shown to the user,
	/// but when computing context, keeping within the bounds of the
	/// call instruction is what the user expects to see.
	///
	/// \param [out] address
	/// An Address object that will be filled in, if a PC can be retrieved.
	///
	/// \return
	/// Returns true if the Address param was filled in.
	bool GetPCForSymbolication(Address &address);

	bool SetPC(uint64_t pc);

	bool SetPC(Address addr);

	uint64_t GetSP(uint64_t fail_value = LLDB_INVALID_ADDRESS);

	bool SetSP(uint64_t sp);

	uint64_t GetFP(uint64_t fail_value = LLDB_INVALID_ADDRESS);

	bool SetFP(uint64_t fp);

	const char *GetRegisterName(uint32_t reg);

	uint64_t GetReturnAddress(uint64_t fail_value = LLDB_INVALID_ADDRESS);

	uint64_t GetFlags(uint64_t fail_value = 0);

	uint64_t ReadRegisterAsUnsigned(uint32_t reg, uint64_t fail_value);

	uint64_t ReadRegisterAsUnsigned(const RegisterInfo *reg_info,
	uint64_t fail_value);

	bool WriteRegisterFromUnsigned(uint32_t reg, uint64_t uval);

	bool WriteRegisterFromUnsigned(const RegisterInfo *reg_info, uint64_t uval);

	bool ConvertBetweenRegisterKinds(lldb::RegisterKind source_rk,
	uint32_t source_regnum,
	lldb::RegisterKind target_rk,
	uint32_t &target_regnum);

	// 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;

	uint32_t GetStopID() const { return m_stop_id; }

	void SetStopID(uint32_t stop_id) { m_stop_id = stop_id; }

	protected:
	/// Indicates that this frame is currently executing code,
	/// that the PC value is not a return-pc but an actual executing
	/// instruction. Some places in lldb will treat a return-pc
	/// value differently than the currently-executing-pc value,
	/// and this method can indicate if that should be done.
	/// The base class implementation only uses the frame index,
	/// but subclasses may have additional information that they
	/// can use to detect frames in this state, for instance a
	/// frame above a trap handler (sigtramp etc)..
	virtual bool BehavesLikeZerothFrame() const {
	return m_concrete_frame_idx == 0;
	}

	// Classes that inherit from RegisterContext can see and modify these
	Thread &m_thread; // The thread that this register context belongs to.
	uint32_t m_concrete_frame_idx; // The concrete frame index for this register
	// context
	uint32_t m_stop_id; // The stop ID that any data in this context is valid for
	private:
	// For RegisterContext only
	RegisterContext(const RegisterContext &) = delete;
	const RegisterContext &operator=(const RegisterContext &) = delete;
	};

	} // namespace lldb_private

	#endif // LLDB_TARGET_REGISTERCONTEXT_H