gdb/gmp-utils.h - binutils-gdb - Git at Google

 /* Miscellaneous routines making it easier to use GMP within GDB's framework.

    Copyright (C) 2019-2021 Free Software Foundation, Inc.

    This file is part of GDB.

    This program is free software; you can redistribute it and/or modify
    it under the terms of the GNU General Public License as published by
    the Free Software Foundation; either version 3 of the License, or
    (at your option) any later version.

    This program is distributed in the hope that it will be useful,
    but WITHOUT ANY WARRANTY; without even the implied warranty of
    MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
    GNU General Public License for more details.

    You should have received a copy of the GNU General Public License
    along with this program.  If not, see <http://www.gnu.org/licenses/>.  */

 #ifndef GMP_UTILS_H
 #define GMP_UTILS_H

 #include "defs.h"

 /* Include <stdio.h> and <stdarg.h> ahead of <gmp.h>, so as to get
    access to GMP's various formatting functions.  */
 #include <stdio.h>
 #include <stdarg.h>
 #include <gmp.h>
 #include "gdbsupport/traits.h"

 /* Same as gmp_asprintf, but returning an std::string.  */

 std::string gmp_string_printf (const char *fmt, ...);

 /* A class to make it easier to use GMP's mpz_t values within GDB.  */

 struct gdb_mpz
 {
   mpz_t val;

   /* Constructors.  */
   gdb_mpz () { mpz_init (val); }

   explicit gdb_mpz (const mpz_t &from_val)
   {
     mpz_init (val);
     mpz_set (val, from_val);
   }

   gdb_mpz (const gdb_mpz &from)
   {
     mpz_init (val);
     mpz_set (val, from.val);
   }

   /* Initialize using the given integral value.

      The main advantage of this method is that it handles both signed
      and unsigned types, with no size restriction.  */
   template<typename T, typename = gdb::Requires<std::is_integral<T>>>
   explicit gdb_mpz (T src)
   {
     mpz_init (val);
     set (src);
   }

   explicit gdb_mpz (gdb_mpz &&from)
   {
     mpz_init (val);
     mpz_swap (val, from.val);
   }


   gdb_mpz &operator= (const gdb_mpz &from)
   {
     mpz_set (val, from.val);
     return *this;
   }

   gdb_mpz &operator= (gdb_mpz &&other)
   {
     mpz_swap (val, other.val);
     return *this;
   }

   template<typename T, typename = gdb::Requires<std::is_integral<T>>>
   gdb_mpz &operator= (T src)
   {
     set (src);
     return *this;
   }

   /* Convert VAL to an integer of the given type.

      The return type can signed or unsigned, with no size restriction.  */
   template<typename T> T as_integer () const;

   /* Set VAL by importing the number stored in the byte array (BUF),
      using the given BYTE_ORDER.  The size of the data to read is
      the byte array's size.

      UNSIGNED_P indicates whether the number has an unsigned type.  */
   void read (gdb::array_view<const gdb_byte> buf, enum bfd_endian byte_order,
 	     bool unsigned_p);

   /* Write VAL into BUF as a number whose byte size is the size of BUF,
      using the given BYTE_ORDER.

      UNSIGNED_P indicates whether the number has an unsigned type.  */
   void write (gdb::array_view<gdb_byte> buf, enum bfd_endian byte_order,
 	      bool unsigned_p) const;

   /* Return a string containing VAL.  */
   std::string str () const { return gmp_string_printf ("%Zd", val); }

   /* The destructor.  */
   ~gdb_mpz () { mpz_clear (val); }

 private:

   /* Helper template for constructor and operator=.  */
   template<typename T> void set (T src);

   /* Low-level function to export VAL into BUF as a number whose byte size
      is the size of BUF.

      If UNSIGNED_P is true, then export VAL into BUF as an unsigned value.
      Otherwise, export it as a signed value.

      The API is inspired from GMP's mpz_export, hence the naming and types
      of the following parameter:
        - ENDIAN should be:
            . 1 for most significant byte first; or
 	   . -1 for least significant byte first; or
 	   . 0 for native endianness.

     An error is raised if BUF is not large enough to contain the value
     being exported.  */
   void safe_export (gdb::array_view<gdb_byte> buf,
 		    int endian, bool unsigned_p) const;
 };

 /* A class to make it easier to use GMP's mpq_t values within GDB.  */

 struct gdb_mpq
 {
   mpq_t val;

   /* Constructors.  */
   gdb_mpq () { mpq_init (val); }

   explicit gdb_mpq (const mpq_t &from_val)
   {
     mpq_init (val);
     mpq_set (val, from_val);
   }

   gdb_mpq (const gdb_mpq &from)
   {
     mpq_init (val);
     mpq_set (val, from.val);
   }

   explicit gdb_mpq (gdb_mpq &&from)
   {
     mpq_init (val);
     mpq_swap (val, from.val);
   }

   /* Copy assignment operator.  */
   gdb_mpq &operator= (const gdb_mpq &from)
   {
     mpq_set (val, from.val);
     return *this;
   }

   gdb_mpq &operator= (gdb_mpq &&from)
   {
     mpq_swap (val, from.val);
     return *this;
   }

   /* Return a string representing VAL as "<numerator> / <denominator>".  */
   std::string str () const { return gmp_string_printf ("%Qd", val); }

   /* Return VAL rounded to the nearest integer.  */
   gdb_mpz get_rounded () const;

   /* Set VAL from the contents of the given byte array (BUF), which
      contains the unscaled value of a fixed point type object.
      The byte size of the data is the size of BUF.

      BYTE_ORDER provides the byte_order to use when reading the data.

      UNSIGNED_P indicates whether the number has an unsigned type.
      SCALING_FACTOR is the scaling factor to apply after having
      read the unscaled value from our buffer.  */
   void read_fixed_point (gdb::array_view<const gdb_byte> buf,
 			 enum bfd_endian byte_order, bool unsigned_p,
 			 const gdb_mpq &scaling_factor);

   /* Write VAL into BUF as fixed point value following the given BYTE_ORDER.
      The size of BUF is used as the length to write the value into.

      UNSIGNED_P indicates whether the number has an unsigned type.
      SCALING_FACTOR is the scaling factor to apply before writing
      the unscaled value to our buffer.  */
   void write_fixed_point (gdb::array_view<gdb_byte> buf,
 			  enum bfd_endian byte_order, bool unsigned_p,
 			  const gdb_mpq &scaling_factor) const;

   /* The destructor.  */
   ~gdb_mpq () { mpq_clear (val); }
 };

 /* A class to make it easier to use GMP's mpf_t values within GDB.

    Should MPFR become a required dependency, we should probably
    drop this class in favor of using MPFR.  */

 struct gdb_mpf
 {
   mpf_t val;

   /* Constructors.  */
   gdb_mpf () { mpf_init (val); }

   DISABLE_COPY_AND_ASSIGN (gdb_mpf);

   /* Set VAL from the contents of the given buffer (BUF), which
      contains the unscaled value of a fixed point type object
      with the given size (LEN) and byte order (BYTE_ORDER).

      UNSIGNED_P indicates whether the number has an unsigned type.
      SCALING_FACTOR is the scaling factor to apply after having
      read the unscaled value from our buffer.  */
   void read_fixed_point (gdb::array_view<const gdb_byte> buf,
 			 enum bfd_endian byte_order, bool unsigned_p,
 			 const gdb_mpq &scaling_factor)
   {
     gdb_mpq tmp_q;

     tmp_q.read_fixed_point (buf, byte_order, unsigned_p, scaling_factor);
     mpf_set_q (val, tmp_q.val);
   }

   /* The destructor.  */
   ~gdb_mpf () { mpf_clear (val); }
 };

 /* See declaration above.  */

 template<typename T>
 void
 gdb_mpz::set (T src)
 {
   mpz_import (val, 1 /* count */, -1 /* order */,
 	      sizeof (T) /* size */, 0 /* endian (0 = native) */,
 	      0 /* nails */, &src /* op */);
   if (std::is_signed<T>::value && src < 0)
     {
       /* mpz_import does not handle the sign, so our value was imported
 	 as an unsigned. Adjust that imported value so as to make it
 	 the correct negative value.  */
       gdb_mpz neg_offset;

       mpz_ui_pow_ui (neg_offset.val, 2, sizeof (T) * HOST_CHAR_BIT);
       mpz_sub (val, val, neg_offset.val);
     }
 }

 /* See declaration above.  */

 template<typename T>
 T
 gdb_mpz::as_integer () const
 {
   T result;

   this->safe_export ({(gdb_byte *) &result, sizeof (result)},
 		     0 /* endian (0 = native) */,
 		     !std::is_signed<T>::value /* unsigned_p */);

   return result;
 }

 #endif
	/* Miscellaneous routines making it easier to use GMP within GDB's framework.

	Copyright (C) 2019-2021 Free Software Foundation, Inc.

	This file is part of GDB.

	This program is free software; you can redistribute it and/or modify
	it under the terms of the GNU General Public License as published by
	the Free Software Foundation; either version 3 of the License, or
	(at your option) any later version.

	This program is distributed in the hope that it will be useful,
	but WITHOUT ANY WARRANTY; without even the implied warranty of
	MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
	GNU General Public License for more details.

	You should have received a copy of the GNU General Public License
	along with this program. If not, see <http://www.gnu.org/licenses/>. */

	#ifndef GMP_UTILS_H
	#define GMP_UTILS_H

	#include "defs.h"

	/* Include <stdio.h> and <stdarg.h> ahead of <gmp.h>, so as to get
	access to GMP's various formatting functions. */
	#include <stdio.h>
	#include <stdarg.h>
	#include <gmp.h>
	#include "gdbsupport/traits.h"

	/* Same as gmp_asprintf, but returning an std::string. */

	std::string gmp_string_printf (const char *fmt, ...);

	/* A class to make it easier to use GMP's mpz_t values within GDB. */

	struct gdb_mpz
	{
	mpz_t val;

	/* Constructors. */
	gdb_mpz () { mpz_init (val); }

	explicit gdb_mpz (const mpz_t &from_val)
	{
	mpz_init (val);
	mpz_set (val, from_val);
	}

	gdb_mpz (const gdb_mpz &from)
	{
	mpz_init (val);
	mpz_set (val, from.val);
	}

	/* Initialize using the given integral value.

	The main advantage of this method is that it handles both signed
	and unsigned types, with no size restriction. */
	template<typename T, typename = gdb::Requires<std::is_integral<T>>>
	explicit gdb_mpz (T src)
	{
	mpz_init (val);
	set (src);
	}

	explicit gdb_mpz (gdb_mpz &&from)
	{
	mpz_init (val);
	mpz_swap (val, from.val);
	}


	gdb_mpz &operator= (const gdb_mpz &from)
	{
	mpz_set (val, from.val);
	return *this;
	}

	gdb_mpz &operator= (gdb_mpz &&other)
	{
	mpz_swap (val, other.val);
	return *this;
	}

	template<typename T, typename = gdb::Requires<std::is_integral<T>>>
	gdb_mpz &operator= (T src)
	{
	set (src);
	return *this;
	}

	/* Convert VAL to an integer of the given type.

	The return type can signed or unsigned, with no size restriction. */
	template<typename T> T as_integer () const;

	/* Set VAL by importing the number stored in the byte array (BUF),
	using the given BYTE_ORDER. The size of the data to read is
	the byte array's size.

	UNSIGNED_P indicates whether the number has an unsigned type. */
	void read (gdb::array_view<const gdb_byte> buf, enum bfd_endian byte_order,
	bool unsigned_p);

	/* Write VAL into BUF as a number whose byte size is the size of BUF,
	using the given BYTE_ORDER.

	UNSIGNED_P indicates whether the number has an unsigned type. */
	void write (gdb::array_view<gdb_byte> buf, enum bfd_endian byte_order,
	bool unsigned_p) const;

	/* Return a string containing VAL. */
	std::string str () const { return gmp_string_printf ("%Zd", val); }

	/* The destructor. */
	~gdb_mpz () { mpz_clear (val); }

	private:

	/* Helper template for constructor and operator=. */
	template<typename T> void set (T src);

	/* Low-level function to export VAL into BUF as a number whose byte size
	is the size of BUF.

	If UNSIGNED_P is true, then export VAL into BUF as an unsigned value.
	Otherwise, export it as a signed value.

	The API is inspired from GMP's mpz_export, hence the naming and types
	of the following parameter:
	- ENDIAN should be:
	. 1 for most significant byte first; or
	. -1 for least significant byte first; or
	. 0 for native endianness.

	An error is raised if BUF is not large enough to contain the value
	being exported. */
	void safe_export (gdb::array_view<gdb_byte> buf,
	int endian, bool unsigned_p) const;
	};

	/* A class to make it easier to use GMP's mpq_t values within GDB. */

	struct gdb_mpq
	{
	mpq_t val;

	/* Constructors. */
	gdb_mpq () { mpq_init (val); }

	explicit gdb_mpq (const mpq_t &from_val)
	{
	mpq_init (val);
	mpq_set (val, from_val);
	}

	gdb_mpq (const gdb_mpq &from)
	{
	mpq_init (val);
	mpq_set (val, from.val);
	}

	explicit gdb_mpq (gdb_mpq &&from)
	{
	mpq_init (val);
	mpq_swap (val, from.val);
	}

	/* Copy assignment operator. */
	gdb_mpq &operator= (const gdb_mpq &from)
	{
	mpq_set (val, from.val);
	return *this;
	}

	gdb_mpq &operator= (gdb_mpq &&from)
	{
	mpq_swap (val, from.val);
	return *this;
	}

	/* Return a string representing VAL as "<numerator> / <denominator>". */
	std::string str () const { return gmp_string_printf ("%Qd", val); }

	/* Return VAL rounded to the nearest integer. */
	gdb_mpz get_rounded () const;

	/* Set VAL from the contents of the given byte array (BUF), which
	contains the unscaled value of a fixed point type object.
	The byte size of the data is the size of BUF.

	BYTE_ORDER provides the byte_order to use when reading the data.

	UNSIGNED_P indicates whether the number has an unsigned type.
	SCALING_FACTOR is the scaling factor to apply after having
	read the unscaled value from our buffer. */
	void read_fixed_point (gdb::array_view<const gdb_byte> buf,
	enum bfd_endian byte_order, bool unsigned_p,
	const gdb_mpq &scaling_factor);

	/* Write VAL into BUF as fixed point value following the given BYTE_ORDER.
	The size of BUF is used as the length to write the value into.

	UNSIGNED_P indicates whether the number has an unsigned type.
	SCALING_FACTOR is the scaling factor to apply before writing
	the unscaled value to our buffer. */
	void write_fixed_point (gdb::array_view<gdb_byte> buf,
	enum bfd_endian byte_order, bool unsigned_p,
	const gdb_mpq &scaling_factor) const;

	/* The destructor. */
	~gdb_mpq () { mpq_clear (val); }
	};

	/* A class to make it easier to use GMP's mpf_t values within GDB.

	Should MPFR become a required dependency, we should probably
	drop this class in favor of using MPFR. */

	struct gdb_mpf
	{
	mpf_t val;

	/* Constructors. */
	gdb_mpf () { mpf_init (val); }

	DISABLE_COPY_AND_ASSIGN (gdb_mpf);

	/* Set VAL from the contents of the given buffer (BUF), which
	contains the unscaled value of a fixed point type object
	with the given size (LEN) and byte order (BYTE_ORDER).

	UNSIGNED_P indicates whether the number has an unsigned type.
	SCALING_FACTOR is the scaling factor to apply after having
	read the unscaled value from our buffer. */
	void read_fixed_point (gdb::array_view<const gdb_byte> buf,
	enum bfd_endian byte_order, bool unsigned_p,
	const gdb_mpq &scaling_factor)
	{
	gdb_mpq tmp_q;

	tmp_q.read_fixed_point (buf, byte_order, unsigned_p, scaling_factor);
	mpf_set_q (val, tmp_q.val);
	}

	/* The destructor. */
	~gdb_mpf () { mpf_clear (val); }
	};

	/* See declaration above. */

	template<typename T>
	void
	gdb_mpz::set (T src)
	{
	mpz_import (val, 1 /* count /, -1 / order */,
	sizeof (T) /* size /, 0 / endian (0 = native) */,
	0 /* nails /, &src / op */);
	if (std::is_signed<T>::value && src < 0)
	{
	/* mpz_import does not handle the sign, so our value was imported
	as an unsigned. Adjust that imported value so as to make it
	the correct negative value. */
	gdb_mpz neg_offset;

	mpz_ui_pow_ui (neg_offset.val, 2, sizeof (T) * HOST_CHAR_BIT);
	mpz_sub (val, val, neg_offset.val);
	}
	}

	/* See declaration above. */

	template<typename T>
	T
	gdb_mpz::as_integer () const
	{
	T result;

	this->safe_export ({(gdb_byte *) &result, sizeof (result)},
	0 /* endian (0 = native) */,
	!std::is_signed<T>::value /* unsigned_p */);

	return result;
	}

	#endif