armv7a/usr/include/lldb/Utility/Scalar.h - manifest_repos/toolchain - Git at Google

 //===-- Scalar.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_UTILITY_SCALAR_H
 #define LLDB_UTILITY_SCALAR_H

 #include "lldb/Utility/LLDBAssert.h"
 #include "lldb/Utility/Status.h"
 #include "lldb/lldb-enumerations.h"
 #include "lldb/lldb-private-types.h"
 #include "llvm/ADT/APFloat.h"
 #include "llvm/ADT/APSInt.h"
 #include <cstddef>
 #include <cstdint>
 #include <utility>

 namespace lldb_private {

 class DataExtractor;
 class Stream;

 #define NUM_OF_WORDS_INT128 2
 #define BITWIDTH_INT128 128

 // A class designed to hold onto values and their corresponding types.
 // Operators are defined and Scalar objects will correctly promote their types
 // and values before performing these operations. Type promotion currently
 // follows the ANSI C type promotion rules.
 class Scalar {
   template<typename T>
   static llvm::APSInt MakeAPSInt(T v) {
     static_assert(std::is_integral<T>::value, "");
     static_assert(sizeof(T) <= sizeof(uint64_t), "Conversion loses precision!");
     return llvm::APSInt(
         llvm::APInt(sizeof(T) * 8, uint64_t(v), std::is_signed<T>::value),
         std::is_unsigned<T>::value);
   }

 public:
   enum Type {
     e_void = 0,
     e_int,
     e_float,
   };

   // Constructors and Destructors
   Scalar() : m_float(0.0f) {}
   Scalar(int v) : m_type(e_int), m_integer(MakeAPSInt(v)), m_float(0.0f) {}
   Scalar(unsigned int v)
       : m_type(e_int), m_integer(MakeAPSInt(v)), m_float(0.0f) {}
   Scalar(long v) : m_type(e_int), m_integer(MakeAPSInt(v)), m_float(0.0f) {}
   Scalar(unsigned long v)
       : m_type(e_int), m_integer(MakeAPSInt(v)), m_float(0.0f) {}
   Scalar(long long v)
       : m_type(e_int), m_integer(MakeAPSInt(v)), m_float(0.0f) {}
   Scalar(unsigned long long v)
       : m_type(e_int), m_integer(MakeAPSInt(v)), m_float(0.0f) {}
   Scalar(float v) : m_type(e_float), m_float(v) {}
   Scalar(double v) : m_type(e_float), m_float(v) {}
   Scalar(long double v) : m_type(e_float), m_float(double(v)) {
     bool ignore;
     m_float.convert(llvm::APFloat::x87DoubleExtended(),
                     llvm::APFloat::rmNearestTiesToEven, &ignore);
   }
   Scalar(llvm::APInt v)
       : m_type(e_int), m_integer(std::move(v), false), m_float(0.0f) {}
   Scalar(llvm::APSInt v)
       : m_type(e_int), m_integer(std::move(v)), m_float(0.0f) {}

   bool SignExtend(uint32_t bit_pos);

   bool ExtractBitfield(uint32_t bit_size, uint32_t bit_offset);

   bool SetBit(uint32_t bit);

   bool ClearBit(uint32_t bit);

   /// Store the binary representation of this value into the given storage.
   /// Exactly GetByteSize() bytes will be stored, and the buffer must be large
   /// enough to hold this data.
   void GetBytes(llvm::MutableArrayRef<uint8_t> storage) const;

   size_t GetByteSize() const;

   bool GetData(DataExtractor &data, size_t limit_byte_size = UINT32_MAX) const;

   size_t GetAsMemoryData(void *dst, size_t dst_len,
                          lldb::ByteOrder dst_byte_order, Status &error) const;

   bool IsZero() const;

   void Clear() {
     m_type = e_void;
     m_integer.clearAllBits();
   }

   const char *GetTypeAsCString() const { return GetValueTypeAsCString(m_type); }

   void GetValue(Stream *s, bool show_type) const;

   bool IsValid() const { return (m_type >= e_int) && (m_type <= e_float); }

   /// Convert to an integer with \p bits and the given signedness.
   void TruncOrExtendTo(uint16_t bits, bool sign);

   bool IntegralPromote(uint16_t bits, bool sign);
   bool FloatPromote(const llvm::fltSemantics &semantics);

   bool IsSigned() const;
   bool MakeSigned();

   bool MakeUnsigned();

   static const char *GetValueTypeAsCString(Scalar::Type value_type);

   // All operators can benefits from the implicit conversions that will happen
   // automagically by the compiler, so no temporary objects will need to be
   // created. As a result, we currently don't need a variety of overloaded set
   // value accessors.
   Scalar &operator+=(Scalar rhs);
   Scalar &operator<<=(const Scalar &rhs); // Shift left
   Scalar &operator>>=(const Scalar &rhs); // Shift right (arithmetic)
   Scalar &operator&=(const Scalar &rhs);

   // Shifts the current value to the right without maintaining the current sign
   // of the value (if it is signed).
   bool ShiftRightLogical(const Scalar &rhs); // Returns true on success

   // Takes the absolute value of the current value if it is signed, else the
   // value remains unchanged. Returns false if the contained value has a void
   // type.
   bool AbsoluteValue(); // Returns true on success
   // Negates the current value (even for unsigned values). Returns false if the
   // contained value has a void type.
   bool UnaryNegate(); // Returns true on success
   // Inverts all bits in the current value as long as it isn't void or a
   // float/double/long double type. Returns false if the contained value has a
   // void/float/double/long double type, else the value is inverted and true is
   // returned.
   bool OnesComplement(); // Returns true on success

   // Access the type of the current value.
   Scalar::Type GetType() const { return m_type; }

   // Returns a casted value of the current contained data without modifying the
   // current value. FAIL_VALUE will be returned if the type of the value is
   // void or invalid.
   int SInt(int fail_value = 0) const;

   unsigned char UChar(unsigned char fail_value = 0) const;

   signed char SChar(signed char fail_value = 0) const;

   unsigned short UShort(unsigned short fail_value = 0) const;

   short SShort(short fail_value = 0) const;

   unsigned int UInt(unsigned int fail_value = 0) const;

   long SLong(long fail_value = 0) const;

   unsigned long ULong(unsigned long fail_value = 0) const;

   long long SLongLong(long long fail_value = 0) const;

   unsigned long long ULongLong(unsigned long long fail_value = 0) const;

   llvm::APInt SInt128(const llvm::APInt &fail_value) const;

   llvm::APInt UInt128(const llvm::APInt &fail_value) const;

   float Float(float fail_value = 0.0f) const;

   double Double(double fail_value = 0.0) const;

   long double LongDouble(long double fail_value = 0.0) const;

   Status SetValueFromCString(const char *s, lldb::Encoding encoding,
                              size_t byte_size);

   Status SetValueFromData(const DataExtractor &data, lldb::Encoding encoding,
                           size_t byte_size);

 protected:
   Scalar::Type m_type = e_void;
   llvm::APSInt m_integer;
   llvm::APFloat m_float;

   template <typename T> T GetAs(T fail_value) const;

   static Type PromoteToMaxType(Scalar &lhs, Scalar &rhs);

   using PromotionKey = std::tuple<Type, unsigned, bool>;
   PromotionKey GetPromoKey() const;

   static PromotionKey GetFloatPromoKey(const llvm::fltSemantics &semantics);

 private:
   friend const Scalar operator+(const Scalar &lhs, const Scalar &rhs);
   friend const Scalar operator-(Scalar lhs, Scalar rhs);
   friend const Scalar operator/(Scalar lhs, Scalar rhs);
   friend const Scalar operator*(Scalar lhs, Scalar rhs);
   friend const Scalar operator&(Scalar lhs, Scalar rhs);
   friend const Scalar operator|(Scalar lhs, Scalar rhs);
   friend const Scalar operator%(Scalar lhs, Scalar rhs);
   friend const Scalar operator^(Scalar lhs, Scalar rhs);
   friend const Scalar operator<<(const Scalar &lhs, const Scalar &rhs);
   friend const Scalar operator>>(const Scalar &lhs, const Scalar &rhs);
   friend bool operator==(Scalar lhs, Scalar rhs);
   friend bool operator!=(const Scalar &lhs, const Scalar &rhs);
   friend bool operator<(Scalar lhs, Scalar rhs);
   friend bool operator<=(const Scalar &lhs, const Scalar &rhs);
   friend bool operator>(const Scalar &lhs, const Scalar &rhs);
   friend bool operator>=(const Scalar &lhs, const Scalar &rhs);
 };

 // Split out the operators into a format where the compiler will be able to
 // implicitly convert numbers into Scalar objects.
 //
 // This allows code like:
 //      Scalar two(2);
 //      Scalar four = two * 2;
 //      Scalar eight = 2 * four;    // This would cause an error if the
 //                                  // operator* was implemented as a
 //                                  // member function.
 // SEE:
 //  Item 19 of "Effective C++ Second Edition" by Scott Meyers
 //  Differentiate among members functions, non-member functions, and
 //  friend functions
 const Scalar operator+(const Scalar &lhs, const Scalar &rhs);
 const Scalar operator-(Scalar lhs, Scalar rhs);
 const Scalar operator/(Scalar lhs, Scalar rhs);
 const Scalar operator*(Scalar lhs, Scalar rhs);
 const Scalar operator&(Scalar lhs, Scalar rhs);
 const Scalar operator|(Scalar lhs, Scalar rhs);
 const Scalar operator%(Scalar lhs, Scalar rhs);
 const Scalar operator^(Scalar lhs, Scalar rhs);
 const Scalar operator<<(const Scalar &lhs, const Scalar &rhs);
 const Scalar operator>>(const Scalar &lhs, const Scalar &rhs);
 bool operator==(Scalar lhs, Scalar rhs);
 bool operator!=(const Scalar &lhs, const Scalar &rhs);
 bool operator<(Scalar lhs, Scalar rhs);
 bool operator<=(const Scalar &lhs, const Scalar &rhs);
 bool operator>(const Scalar &lhs, const Scalar &rhs);
 bool operator>=(const Scalar &lhs, const Scalar &rhs);

 llvm::raw_ostream &operator<<(llvm::raw_ostream &os, const Scalar &scalar);

 } // namespace lldb_private

 #endif // LLDB_UTILITY_SCALAR_H
	//===-- Scalar.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_UTILITY_SCALAR_H
	#define LLDB_UTILITY_SCALAR_H

	#include "lldb/Utility/LLDBAssert.h"
	#include "lldb/Utility/Status.h"
	#include "lldb/lldb-enumerations.h"
	#include "lldb/lldb-private-types.h"
	#include "llvm/ADT/APFloat.h"
	#include "llvm/ADT/APSInt.h"
	#include <cstddef>
	#include <cstdint>
	#include <utility>

	namespace lldb_private {

	class DataExtractor;
	class Stream;

	#define NUM_OF_WORDS_INT128 2
	#define BITWIDTH_INT128 128

	// A class designed to hold onto values and their corresponding types.
	// Operators are defined and Scalar objects will correctly promote their types
	// and values before performing these operations. Type promotion currently
	// follows the ANSI C type promotion rules.
	class Scalar {
	template<typename T>
	static llvm::APSInt MakeAPSInt(T v) {
	static_assert(std::is_integral<T>::value, "");
	static_assert(sizeof(T) <= sizeof(uint64_t), "Conversion loses precision!");
	return llvm::APSInt(
	llvm::APInt(sizeof(T) * 8, uint64_t(v), std::is_signed<T>::value),
	std::is_unsigned<T>::value);
	}

	public:
	enum Type {
	e_void = 0,
	e_int,
	e_float,
	};

	// Constructors and Destructors
	Scalar() : m_float(0.0f) {}
	Scalar(int v) : m_type(e_int), m_integer(MakeAPSInt(v)), m_float(0.0f) {}
	Scalar(unsigned int v)
	: m_type(e_int), m_integer(MakeAPSInt(v)), m_float(0.0f) {}
	Scalar(long v) : m_type(e_int), m_integer(MakeAPSInt(v)), m_float(0.0f) {}
	Scalar(unsigned long v)
	: m_type(e_int), m_integer(MakeAPSInt(v)), m_float(0.0f) {}
	Scalar(long long v)
	: m_type(e_int), m_integer(MakeAPSInt(v)), m_float(0.0f) {}
	Scalar(unsigned long long v)
	: m_type(e_int), m_integer(MakeAPSInt(v)), m_float(0.0f) {}
	Scalar(float v) : m_type(e_float), m_float(v) {}
	Scalar(double v) : m_type(e_float), m_float(v) {}
	Scalar(long double v) : m_type(e_float), m_float(double(v)) {
	bool ignore;
	m_float.convert(llvm::APFloat::x87DoubleExtended(),
	llvm::APFloat::rmNearestTiesToEven, &ignore);
	}
	Scalar(llvm::APInt v)
	: m_type(e_int), m_integer(std::move(v), false), m_float(0.0f) {}
	Scalar(llvm::APSInt v)
	: m_type(e_int), m_integer(std::move(v)), m_float(0.0f) {}

	bool SignExtend(uint32_t bit_pos);

	bool ExtractBitfield(uint32_t bit_size, uint32_t bit_offset);

	bool SetBit(uint32_t bit);

	bool ClearBit(uint32_t bit);

	/// Store the binary representation of this value into the given storage.
	/// Exactly GetByteSize() bytes will be stored, and the buffer must be large
	/// enough to hold this data.
	void GetBytes(llvm::MutableArrayRef<uint8_t> storage) const;

	size_t GetByteSize() const;

	bool GetData(DataExtractor &data, size_t limit_byte_size = UINT32_MAX) const;

	size_t GetAsMemoryData(void *dst, size_t dst_len,
	lldb::ByteOrder dst_byte_order, Status &error) const;

	bool IsZero() const;

	void Clear() {
	m_type = e_void;
	m_integer.clearAllBits();
	}

	const char *GetTypeAsCString() const { return GetValueTypeAsCString(m_type); }

	void GetValue(Stream *s, bool show_type) const;

	bool IsValid() const { return (m_type >= e_int) && (m_type <= e_float); }

	/// Convert to an integer with \p bits and the given signedness.
	void TruncOrExtendTo(uint16_t bits, bool sign);

	bool IntegralPromote(uint16_t bits, bool sign);
	bool FloatPromote(const llvm::fltSemantics &semantics);

	bool IsSigned() const;
	bool MakeSigned();

	bool MakeUnsigned();

	static const char *GetValueTypeAsCString(Scalar::Type value_type);

	// All operators can benefits from the implicit conversions that will happen
	// automagically by the compiler, so no temporary objects will need to be
	// created. As a result, we currently don't need a variety of overloaded set
	// value accessors.
	Scalar &operator+=(Scalar rhs);
	Scalar &operator<<=(const Scalar &rhs); // Shift left
	Scalar &operator>>=(const Scalar &rhs); // Shift right (arithmetic)
	Scalar &operator&=(const Scalar &rhs);

	// Shifts the current value to the right without maintaining the current sign
	// of the value (if it is signed).
	bool ShiftRightLogical(const Scalar &rhs); // Returns true on success

	// Takes the absolute value of the current value if it is signed, else the
	// value remains unchanged. Returns false if the contained value has a void
	// type.
	bool AbsoluteValue(); // Returns true on success
	// Negates the current value (even for unsigned values). Returns false if the
	// contained value has a void type.
	bool UnaryNegate(); // Returns true on success
	// Inverts all bits in the current value as long as it isn't void or a
	// float/double/long double type. Returns false if the contained value has a
	// void/float/double/long double type, else the value is inverted and true is
	// returned.
	bool OnesComplement(); // Returns true on success

	// Access the type of the current value.
	Scalar::Type GetType() const { return m_type; }

	// Returns a casted value of the current contained data without modifying the
	// current value. FAIL_VALUE will be returned if the type of the value is
	// void or invalid.
	int SInt(int fail_value = 0) const;

	unsigned char UChar(unsigned char fail_value = 0) const;

	signed char SChar(signed char fail_value = 0) const;

	unsigned short UShort(unsigned short fail_value = 0) const;

	short SShort(short fail_value = 0) const;

	unsigned int UInt(unsigned int fail_value = 0) const;

	long SLong(long fail_value = 0) const;

	unsigned long ULong(unsigned long fail_value = 0) const;

	long long SLongLong(long long fail_value = 0) const;

	unsigned long long ULongLong(unsigned long long fail_value = 0) const;

	llvm::APInt SInt128(const llvm::APInt &fail_value) const;

	llvm::APInt UInt128(const llvm::APInt &fail_value) const;

	float Float(float fail_value = 0.0f) const;

	double Double(double fail_value = 0.0) const;

	long double LongDouble(long double fail_value = 0.0) const;

	Status SetValueFromCString(const char *s, lldb::Encoding encoding,
	size_t byte_size);

	Status SetValueFromData(const DataExtractor &data, lldb::Encoding encoding,
	size_t byte_size);

	protected:
	Scalar::Type m_type = e_void;
	llvm::APSInt m_integer;
	llvm::APFloat m_float;

	template <typename T> T GetAs(T fail_value) const;

	static Type PromoteToMaxType(Scalar &lhs, Scalar &rhs);

	using PromotionKey = std::tuple<Type, unsigned, bool>;
	PromotionKey GetPromoKey() const;

	static PromotionKey GetFloatPromoKey(const llvm::fltSemantics &semantics);

	private:
	friend const Scalar operator+(const Scalar &lhs, const Scalar &rhs);
	friend const Scalar operator-(Scalar lhs, Scalar rhs);
	friend const Scalar operator/(Scalar lhs, Scalar rhs);
	friend const Scalar operator*(Scalar lhs, Scalar rhs);
	friend const Scalar operator&(Scalar lhs, Scalar rhs);
	friend const Scalar operator\|(Scalar lhs, Scalar rhs);
	friend const Scalar operator%(Scalar lhs, Scalar rhs);
	friend const Scalar operator^(Scalar lhs, Scalar rhs);
	friend const Scalar operator<<(const Scalar &lhs, const Scalar &rhs);
	friend const Scalar operator>>(const Scalar &lhs, const Scalar &rhs);
	friend bool operator==(Scalar lhs, Scalar rhs);
	friend bool operator!=(const Scalar &lhs, const Scalar &rhs);
	friend bool operator<(Scalar lhs, Scalar rhs);
	friend bool operator<=(const Scalar &lhs, const Scalar &rhs);
	friend bool operator>(const Scalar &lhs, const Scalar &rhs);
	friend bool operator>=(const Scalar &lhs, const Scalar &rhs);
	};

	// Split out the operators into a format where the compiler will be able to
	// implicitly convert numbers into Scalar objects.
	//
	// This allows code like:
	// Scalar two(2);
	// Scalar four = two * 2;
	// Scalar eight = 2 * four; // This would cause an error if the
	// // operator* was implemented as a
	// // member function.
	// SEE:
	// Item 19 of "Effective C++ Second Edition" by Scott Meyers
	// Differentiate among members functions, non-member functions, and
	// friend functions
	const Scalar operator+(const Scalar &lhs, const Scalar &rhs);
	const Scalar operator-(Scalar lhs, Scalar rhs);
	const Scalar operator/(Scalar lhs, Scalar rhs);
	const Scalar operator*(Scalar lhs, Scalar rhs);
	const Scalar operator&(Scalar lhs, Scalar rhs);
	const Scalar operator\|(Scalar lhs, Scalar rhs);
	const Scalar operator%(Scalar lhs, Scalar rhs);
	const Scalar operator^(Scalar lhs, Scalar rhs);
	const Scalar operator<<(const Scalar &lhs, const Scalar &rhs);
	const Scalar operator>>(const Scalar &lhs, const Scalar &rhs);
	bool operator==(Scalar lhs, Scalar rhs);
	bool operator!=(const Scalar &lhs, const Scalar &rhs);
	bool operator<(Scalar lhs, Scalar rhs);
	bool operator<=(const Scalar &lhs, const Scalar &rhs);
	bool operator>(const Scalar &lhs, const Scalar &rhs);
	bool operator>=(const Scalar &lhs, const Scalar &rhs);

	llvm::raw_ostream &operator<<(llvm::raw_ostream &os, const Scalar &scalar);

	} // namespace lldb_private

	#endif // LLDB_UTILITY_SCALAR_H