//===-- RegisterValue.h -----------------------------------------*- C++ -*-===//
//
//                     The LLVM Compiler Infrastructure
//
// This file is distributed under the University of Illinois Open Source
// License. See LICENSE.TXT for details.
//
//===----------------------------------------------------------------------===//

#ifndef lldb_RegisterValue_h
#define lldb_RegisterValue_h

#include "lldb/Core/Scalar.h"
#include "lldb/Utility/Endian.h"
#include "lldb/Utility/Status.h"    // for Status
#include "lldb/lldb-enumerations.h" // for ByteOrder, Format
#include "lldb/lldb-types.h"        // for offset_t

#include "llvm/ADT/APInt.h"
#include "llvm/ADT/StringRef.h" // for StringRef

#include <stdint.h> // for uint32_t, uint8_t, uint64_t, uin...
#include <string.h>

namespace lldb_private {
class DataExtractor;
}
namespace lldb_private {
class Stream;
}
namespace lldb_private {
struct RegisterInfo;
}
namespace lldb_private {

class RegisterValue {
public:
  enum { kMaxRegisterByteSize = 32u };

  enum Type {
    eTypeInvalid,
    eTypeUInt8,
    eTypeUInt16,
    eTypeUInt32,
    eTypeUInt64,
    eTypeUInt128,
    eTypeFloat,
    eTypeDouble,
    eTypeLongDouble,
    eTypeBytes
  };

  RegisterValue() : m_type(eTypeInvalid), m_scalar((unsigned long)0) {}

  explicit RegisterValue(uint8_t inst) : m_type(eTypeUInt8) { m_scalar = inst; }

  explicit RegisterValue(uint16_t inst) : m_type(eTypeUInt16) {
    m_scalar = inst;
  }

  explicit RegisterValue(uint32_t inst) : m_type(eTypeUInt32) {
    m_scalar = inst;
  }

  explicit RegisterValue(uint64_t inst) : m_type(eTypeUInt64) {
    m_scalar = inst;
  }

  explicit RegisterValue(llvm::APInt inst) : m_type(eTypeUInt128) {
    m_scalar = llvm::APInt(inst);
  }

  explicit RegisterValue(float value) : m_type(eTypeFloat) { m_scalar = value; }

  explicit RegisterValue(double value) : m_type(eTypeDouble) {
    m_scalar = value;
  }

  explicit RegisterValue(long double value) : m_type(eTypeLongDouble) {
    m_scalar = value;
  }

  explicit RegisterValue(uint8_t *bytes, size_t length,
                         lldb::ByteOrder byte_order) {
    SetBytes(bytes, length, byte_order);
  }

  RegisterValue::Type GetType() const { return m_type; }

  bool CopyValue(const RegisterValue &rhs);

  void SetType(RegisterValue::Type type) { m_type = type; }

  RegisterValue::Type SetType(const RegisterInfo *reg_info);

  bool GetData(DataExtractor &data) const;

  // Copy the register value from this object into a buffer in "dst"
  // and obey the "dst_byte_order" when copying the data. Also watch out
  // in case "dst_len" is longer or shorter than the register value
  // described by "reg_info" and only copy the least significant bytes
  // of the register value, or pad the destination with zeroes if the
  // register byte size is shorter that "dst_len" (all while correctly
  // abiding the "dst_byte_order"). Returns the number of bytes copied
  // into "dst".
  uint32_t GetAsMemoryData(const RegisterInfo *reg_info, void *dst,
                           uint32_t dst_len, lldb::ByteOrder dst_byte_order,
                           Status &error) const;

  uint32_t SetFromMemoryData(const RegisterInfo *reg_info, const void *src,
                             uint32_t src_len, lldb::ByteOrder src_byte_order,
                             Status &error);

  bool GetScalarValue(Scalar &scalar) const;

  uint8_t GetAsUInt8(uint8_t fail_value = UINT8_MAX,
                     bool *success_ptr = nullptr) const {
    if (m_type == eTypeUInt8) {
      if (success_ptr)
        *success_ptr = true;
      return m_scalar.UChar(fail_value);
    }
    if (success_ptr)
      *success_ptr = true;
    return fail_value;
  }

  uint16_t GetAsUInt16(uint16_t fail_value = UINT16_MAX,
                       bool *success_ptr = nullptr) const;

  uint32_t GetAsUInt32(uint32_t fail_value = UINT32_MAX,
                       bool *success_ptr = nullptr) const;

  uint64_t GetAsUInt64(uint64_t fail_value = UINT64_MAX,
                       bool *success_ptr = nullptr) const;

  llvm::APInt GetAsUInt128(const llvm::APInt &fail_value,
                           bool *success_ptr = nullptr) const;

  float GetAsFloat(float fail_value = 0.0f, bool *success_ptr = nullptr) const;

  double GetAsDouble(double fail_value = 0.0,
                     bool *success_ptr = nullptr) const;

  long double GetAsLongDouble(long double fail_value = 0.0,
                              bool *success_ptr = nullptr) const;

  void SetValueToInvalid() { m_type = eTypeInvalid; }

  bool ClearBit(uint32_t bit);

  bool SetBit(uint32_t bit);

  bool operator==(const RegisterValue &rhs) const;

  bool operator!=(const RegisterValue &rhs) const;

  void operator=(uint8_t uint) {
    m_type = eTypeUInt8;
    m_scalar = uint;
  }

  void operator=(uint16_t uint) {
    m_type = eTypeUInt16;
    m_scalar = uint;
  }

  void operator=(uint32_t uint) {
    m_type = eTypeUInt32;
    m_scalar = uint;
  }

  void operator=(uint64_t uint) {
    m_type = eTypeUInt64;
    m_scalar = uint;
  }

  void operator=(llvm::APInt uint) {
    m_type = eTypeUInt128;
    m_scalar = llvm::APInt(uint);
  }

  void operator=(float f) {
    m_type = eTypeFloat;
    m_scalar = f;
  }

  void operator=(double f) {
    m_type = eTypeDouble;
    m_scalar = f;
  }

  void operator=(long double f) {
    m_type = eTypeLongDouble;
    m_scalar = f;
  }

  void SetUInt8(uint8_t uint) {
    m_type = eTypeUInt8;
    m_scalar = uint;
  }

  void SetUInt16(uint16_t uint) {
    m_type = eTypeUInt16;
    m_scalar = uint;
  }

  void SetUInt32(uint32_t uint, Type t = eTypeUInt32) {
    m_type = t;
    m_scalar = uint;
  }

  void SetUInt64(uint64_t uint, Type t = eTypeUInt64) {
    m_type = t;
    m_scalar = uint;
  }

  void SetUInt128(llvm::APInt uint) {
    m_type = eTypeUInt128;
    m_scalar = uint;
  }

  bool SetUInt(uint64_t uint, uint32_t byte_size);

  void SetFloat(float f) {
    m_type = eTypeFloat;
    m_scalar = f;
  }

  void SetDouble(double f) {
    m_type = eTypeDouble;
    m_scalar = f;
  }

  void SetLongDouble(long double f) {
    m_type = eTypeLongDouble;
    m_scalar = f;
  }

  void SetBytes(const void *bytes, size_t length, lldb::ByteOrder byte_order);

  bool SignExtend(uint32_t sign_bitpos);

  Status SetValueFromString(const RegisterInfo *reg_info,
                            llvm::StringRef value_str);
  Status SetValueFromString(const RegisterInfo *reg_info,
                            const char *value_str) = delete;

  Status SetValueFromData(const RegisterInfo *reg_info, DataExtractor &data,
                          lldb::offset_t offset, bool partial_data_ok);

  // The default value of 0 for reg_name_right_align_at means no alignment at
  // all.
  bool Dump(Stream *s, const RegisterInfo *reg_info, bool prefix_with_name,
            bool prefix_with_alt_name, lldb::Format format,
            uint32_t reg_name_right_align_at = 0) const;

  const void *GetBytes() const;

  lldb::ByteOrder GetByteOrder() const {
    if (m_type == eTypeBytes)
      return buffer.byte_order;
    return endian::InlHostByteOrder();
  }

  uint32_t GetByteSize() const;

  static uint32_t GetMaxByteSize() { return kMaxRegisterByteSize; }

  void Clear();

protected:
  RegisterValue::Type m_type;
  Scalar m_scalar;

  struct {
    uint8_t bytes[kMaxRegisterByteSize]; // This must be big enough to hold any
                                         // register for any supported target.
    uint8_t length;
    lldb::ByteOrder byte_order;
  } buffer;
};

} // namespace lldb_private

#endif // lldb_RegisterValue_h