library/bignum_mod_raw.h - filogic/uboot - Gitiles

 /**
  *  Low-level modular bignum functions
  *
  *  This interface should only be used by the higher-level modular bignum
  *  module (bignum_mod.c) and the ECP module (ecp.c, ecp_curves.c). All other
  *  modules should use the high-level modular bignum interface (bignum_mod.h)
  *  or the legacy bignum interface (bignum.h).
  *
  * This is a low-level interface to operations on integers modulo which
  * has no protection against passing invalid arguments such as arrays of
  * the wrong size. The functions in bignum_mod.h provide a higher-level
  * interface that includes protections against accidental misuse, at the
  * expense of code size and sometimes more cumbersome memory management.
  *
  * The functions in this module obey the following conventions unless
  * explicitly indicated otherwise:
  * - **Modulus parameters**: the modulus is passed as a pointer to a structure
  *   of type #mbedtls_mpi_mod_modulus. The structure must be set up with an
  *   array of limbs storing the bignum value of the modulus. The modulus must
  *   be odd and is assumed to have no leading zeroes. The modulus is usually
  *   named \c N and is usually input-only.
  * - **Bignum parameters**: Bignums are passed as pointers to an array of
  *   limbs. A limb has the type #mbedtls_mpi_uint. Unless otherwise specified:
  *     - Bignum parameters called \c A, \c B, ... are inputs, and are not
  *       modified by the function.
  *     - Bignum parameters called \c X, \c Y are outputs or input-output.
  *       The initial content of output-only parameters is ignored.
  *     - \c T is a temporary storage area. The initial content of such a
  *       parameter is ignored and the final content is unspecified.
  * - **Bignum sizes**: bignum sizes are usually expressed by the \c limbs
  *   member of the modulus argument. All bignum parameters must have the same
  *   number of limbs as the modulus. All bignum sizes must be at least 1 and
  *   must be significantly less than #SIZE_MAX. The behavior if a size is 0 is
  *   undefined.
  * - **Bignum representation**: the representation of inputs and outputs is
  *   specified by the \c int_rep field of the modulus for arithmetic
  *   functions. Utility functions may allow for different representation.
  * - **Parameter ordering**: for bignum parameters, outputs come before inputs.
  *   The modulus is passed after other bignum input parameters. Temporaries
  *   come last.
  * - **Aliasing**: in general, output bignums may be aliased to one or more
  *   inputs. Modulus values may not be aliased to any other parameter. Outputs
  *   may not be aliased to one another. Temporaries may not be aliased to any
  *   other parameter.
  * - **Overlap**: apart from aliasing of limb array pointers (where two
  *   arguments are equal pointers), overlap is not supported and may result
  *   in undefined behavior.
  * - **Error handling**: This is a low-level module. Functions generally do not
  *   try to protect against invalid arguments such as nonsensical sizes or
  *   null pointers. Note that passing bignums with a different size than the
  *   modulus may lead to buffer overflows. Some functions which allocate
  *   memory or handle reading/writing of bignums will return an error if
  *   memory allocation fails or if buffer sizes are invalid.
  * - **Modular representatives**: all functions expect inputs to be in the
  *   range [0, \c N - 1] and guarantee outputs in the range [0, \c N - 1]. If
  *   an input is out of range, outputs are fully unspecified, though bignum
  *   values out of range should not cause buffer overflows (beware that this is
  *   not extensively tested).
  */

 /*
  *  Copyright The Mbed TLS Contributors
  *  SPDX-License-Identifier: Apache-2.0 OR GPL-2.0-or-later
  */

 #ifndef MBEDTLS_BIGNUM_MOD_RAW_H
 #define MBEDTLS_BIGNUM_MOD_RAW_H

 #include "common.h"

 #if defined(MBEDTLS_BIGNUM_C)
 #include "mbedtls/bignum.h"
 #endif

 #include "bignum_mod.h"

 /**
  * \brief   Perform a safe conditional copy of an MPI which doesn't reveal
  *          whether the assignment was done or not.
  *
  * The size to copy is determined by \p N.
  *
  * \param[out] X        The address of the destination MPI.
  *                      This must be initialized. Must have enough limbs to
  *                      store the full value of \p A.
  * \param[in]  A        The address of the source MPI. This must be initialized.
  * \param[in]  N        The address of the modulus related to \p X and \p A.
  * \param      assign   The condition deciding whether to perform the
  *                      assignment or not. Must be either 0 or 1:
  *                      * \c 1: Perform the assignment `X = A`.
  *                      * \c 0: Keep the original value of \p X.
  *
  * \note           This function avoids leaking any information about whether
  *                 the assignment was done or not.
  *
  * \warning        If \p assign is neither 0 nor 1, the result of this function
  *                 is indeterminate, and the resulting value in \p X might be
  *                 neither its original value nor the value in \p A.
  */
 void mbedtls_mpi_mod_raw_cond_assign(mbedtls_mpi_uint *X,
                                      const mbedtls_mpi_uint *A,
                                      const mbedtls_mpi_mod_modulus *N,
                                      unsigned char assign);

 /**
  * \brief   Perform a safe conditional swap of two MPIs which doesn't reveal
  *          whether the swap was done or not.
  *
  * The size to swap is determined by \p N.
  *
  * \param[in,out] X     The address of the first MPI. This must be initialized.
  * \param[in,out] Y     The address of the second MPI. This must be initialized.
  * \param[in]     N     The address of the modulus related to \p X and \p Y.
  * \param         swap  The condition deciding whether to perform
  *                      the swap or not. Must be either 0 or 1:
  *                      * \c 1: Swap the values of \p X and \p Y.
  *                      * \c 0: Keep the original values of \p X and \p Y.
  *
  * \note           This function avoids leaking any information about whether
  *                 the swap was done or not.
  *
  * \warning        If \p swap is neither 0 nor 1, the result of this function
  *                 is indeterminate, and both \p X and \p Y might end up with
  *                 values different to either of the original ones.
  */
 void mbedtls_mpi_mod_raw_cond_swap(mbedtls_mpi_uint *X,
                                    mbedtls_mpi_uint *Y,
                                    const mbedtls_mpi_mod_modulus *N,
                                    unsigned char swap);

 /** Import X from unsigned binary data.
  *
  * The MPI needs to have enough limbs to store the full value (including any
  * most significant zero bytes in the input).
  *
  * \param[out] X        The address of the MPI. The size is determined by \p N.
  *                      (In particular, it must have at least as many limbs as
  *                      the modulus \p N.)
  * \param[in] N         The address of the modulus related to \p X.
  * \param[in] input     The input buffer to import from.
  * \param input_length  The length in bytes of \p input.
  * \param ext_rep       The endianness of the number in the input buffer.
  *
  * \return       \c 0 if successful.
  * \return       #MBEDTLS_ERR_MPI_BUFFER_TOO_SMALL if \p X isn't
  *               large enough to hold the value in \p input.
  * \return       #MBEDTLS_ERR_MPI_BAD_INPUT_DATA if the external representation
  *               of \p N is invalid or \p X is not less than \p N.
  */
 int mbedtls_mpi_mod_raw_read(mbedtls_mpi_uint *X,
                              const mbedtls_mpi_mod_modulus *N,
                              const unsigned char *input,
                              size_t input_length,
                              mbedtls_mpi_mod_ext_rep ext_rep);

 /** Export A into unsigned binary data.
  *
  * \param[in] A         The address of the MPI. The size is determined by \p N.
  *                      (In particular, it must have at least as many limbs as
  *                      the modulus \p N.)
  * \param[in] N         The address of the modulus related to \p A.
  * \param[out] output   The output buffer to export to.
  * \param output_length The length in bytes of \p output.
  * \param ext_rep       The endianness in which the number should be written into the output buffer.
  *
  * \return       \c 0 if successful.
  * \return       #MBEDTLS_ERR_MPI_BUFFER_TOO_SMALL if \p output isn't
  *               large enough to hold the value of \p A.
  * \return       #MBEDTLS_ERR_MPI_BAD_INPUT_DATA if the external representation
  *               of \p N is invalid.
  */
 int mbedtls_mpi_mod_raw_write(const mbedtls_mpi_uint *A,
                               const mbedtls_mpi_mod_modulus *N,
                               unsigned char *output,
                               size_t output_length,
                               mbedtls_mpi_mod_ext_rep ext_rep);

 /** \brief  Subtract two MPIs, returning the residue modulo the specified
  *          modulus.
  *
  * The size of the operation is determined by \p N. \p A and \p B must have
  * the same number of limbs as \p N.
  *
  * \p X may be aliased to \p A or \p B, or even both, but may not overlap
  * either otherwise.
  *
  * \param[out] X        The address of the result MPI.
  *                      This must be initialized. Must have enough limbs to
  *                      store the full value of the result.
  * \param[in]  A        The address of the first MPI. This must be initialized.
  * \param[in]  B        The address of the second MPI. This must be initialized.
  * \param[in]  N        The address of the modulus. Used to perform a modulo
  *                      operation on the result of the subtraction.
  */
 void mbedtls_mpi_mod_raw_sub(mbedtls_mpi_uint *X,
                              const mbedtls_mpi_uint *A,
                              const mbedtls_mpi_uint *B,
                              const mbedtls_mpi_mod_modulus *N);

 /** \brief  Multiply two MPIs, returning the residue modulo the specified
  *          modulus.
  *
  * \note Currently handles the case when `N->int_rep` is
  * MBEDTLS_MPI_MOD_REP_MONTGOMERY.
  *
  * The size of the operation is determined by \p N. \p A, \p B and \p X must
  * all be associated with the modulus \p N and must all have the same number
  * of limbs as \p N.
  *
  * \p X may be aliased to \p A or \p B, or even both, but may not overlap
  * either otherwise. They may not alias \p N (since they must be in canonical
  * form, they cannot == \p N).
  *
  * \param[out] X        The address of the result MPI. Must have the same
  *                      number of limbs as \p N.
  *                      On successful completion, \p X contains the result of
  *                      the multiplication `A * B * R^-1` mod N where
  *                      `R = 2^(biL * N->limbs)`.
  * \param[in]  A        The address of the first MPI.
  * \param[in]  B        The address of the second MPI.
  * \param[in]  N        The address of the modulus. Used to perform a modulo
  *                      operation on the result of the multiplication.
  * \param[in,out] T     Temporary storage of size at least 2 * N->limbs + 1
  *                      limbs. Its initial content is unused and
  *                      its final content is indeterminate.
  *                      It must not alias or otherwise overlap any of the
  *                      other parameters.
  */
 void mbedtls_mpi_mod_raw_mul(mbedtls_mpi_uint *X,
                              const mbedtls_mpi_uint *A,
                              const mbedtls_mpi_uint *B,
                              const mbedtls_mpi_mod_modulus *N,
                              mbedtls_mpi_uint *T);

 /**
  * \brief          Returns the number of limbs of working memory required for
  *                 a call to `mbedtls_mpi_mod_raw_inv_prime()`.
  *
  * \note           This will always be at least
  *                 `mbedtls_mpi_core_montmul_working_limbs(AN_limbs)`,
  *                 i.e. sufficient for a call to `mbedtls_mpi_core_montmul()`.
  *
  * \param AN_limbs The number of limbs in the input `A` and the modulus `N`
  *                 (they must be the same size) that will be given to
  *                 `mbedtls_mpi_mod_raw_inv_prime()`.
  *
  * \return         The number of limbs of working memory required by
  *                 `mbedtls_mpi_mod_raw_inv_prime()`.
  */
 size_t mbedtls_mpi_mod_raw_inv_prime_working_limbs(size_t AN_limbs);

 /**
  * \brief Perform fixed-width modular inversion of a Montgomery-form MPI with
  *        respect to a modulus \p N that must be prime.
  *
  * \p X may be aliased to \p A, but not to \p N or \p RR.
  *
  * \param[out] X     The modular inverse of \p A with respect to \p N.
  *                   Will be in Montgomery form.
  * \param[in] A      The number to calculate the modular inverse of.
  *                   Must be in Montgomery form. Must not be 0.
  * \param[in] N      The modulus, as a little-endian array of length \p AN_limbs.
  *                   Must be prime.
  * \param AN_limbs   The number of limbs in \p A, \p N and \p RR.
  * \param[in] RR     The precomputed residue of 2^{2*biL} modulo N, as a little-
  *                   endian array of length \p AN_limbs.
  * \param[in,out] T  Temporary storage of at least the number of limbs returned
  *                   by `mbedtls_mpi_mod_raw_inv_prime_working_limbs()`.
  *                   Its initial content is unused and its final content is
  *                   indeterminate.
  *                   It must not alias or otherwise overlap any of the other
  *                   parameters.
  *                   It is up to the caller to zeroize \p T when it is no
  *                   longer needed, and before freeing it if it was dynamically
  *                   allocated.
  */
 void mbedtls_mpi_mod_raw_inv_prime(mbedtls_mpi_uint *X,
                                    const mbedtls_mpi_uint *A,
                                    const mbedtls_mpi_uint *N,
                                    size_t AN_limbs,
                                    const mbedtls_mpi_uint *RR,
                                    mbedtls_mpi_uint *T);

 /**
  * \brief Perform a known-size modular addition.
  *
  * Calculate `A + B modulo N`.
  *
  * The number of limbs in each operand, and the result, is given by the
  * modulus \p N.
  *
  * \p X may be aliased to \p A or \p B, or even both, but may not overlap
  * either otherwise.
  *
  * \param[out] X    The result of the modular addition.
  * \param[in] A     Little-endian presentation of the left operand. This
  *                  must be smaller than \p N.
  * \param[in] B     Little-endian presentation of the right operand. This
  *                  must be smaller than \p N.
  * \param[in] N     The address of the modulus.
  */
 void mbedtls_mpi_mod_raw_add(mbedtls_mpi_uint *X,
                              const mbedtls_mpi_uint *A,
                              const mbedtls_mpi_uint *B,
                              const mbedtls_mpi_mod_modulus *N);

 /** Convert an MPI from canonical representation (little-endian limb array)
  * to the representation associated with the modulus.
  *
  * \param[in,out] X The limb array to convert.
  *                  It must have as many limbs as \p N.
  *                  It is converted in place.
  *                  If this function returns an error, the content of \p X
  *                  is unspecified.
  * \param[in] N     The modulus structure.
  *
  * \return          \c 0 if successful.
  *                  Otherwise an \c MBEDTLS_ERR_MPI_xxx error code.
  */
 int mbedtls_mpi_mod_raw_canonical_to_modulus_rep(
     mbedtls_mpi_uint *X,
     const mbedtls_mpi_mod_modulus *N);

 /** Convert an MPI from the representation associated with the modulus
  * to canonical representation (little-endian limb array).
  *
  * \param[in,out] X The limb array to convert.
  *                  It must have as many limbs as \p N.
  *                  It is converted in place.
  *                  If this function returns an error, the content of \p X
  *                  is unspecified.
  * \param[in] N     The modulus structure.
  *
  * \return          \c 0 if successful.
  *                  Otherwise an \c MBEDTLS_ERR_MPI_xxx error code.
  */
 int mbedtls_mpi_mod_raw_modulus_to_canonical_rep(
     mbedtls_mpi_uint *X,
     const mbedtls_mpi_mod_modulus *N);

 /** Generate a random number uniformly in a range.
  *
  * This function generates a random number between \p min inclusive and
  * \p N exclusive.
  *
  * The procedure complies with RFC 6979 §3.3 (deterministic ECDSA)
  * when the RNG is a suitably parametrized instance of HMAC_DRBG
  * and \p min is \c 1.
  *
  * \note           There are `N - min` possible outputs. The lower bound
  *                 \p min can be reached, but the upper bound \p N cannot.
  *
  * \param X        The destination MPI, in canonical representation modulo \p N.
  *                 It must not be aliased with \p N or otherwise overlap it.
  * \param min      The minimum value to return. It must be strictly smaller
  *                 than \b N.
  * \param N        The modulus.
  *                 This is the upper bound of the output range, exclusive.
  * \param f_rng    The RNG function to use. This must not be \c NULL.
  * \param p_rng    The RNG parameter to be passed to \p f_rng.
  *
  * \return         \c 0 if successful.
  * \return         #MBEDTLS_ERR_MPI_NOT_ACCEPTABLE if the implementation was
  *                 unable to find a suitable value within a limited number
  *                 of attempts. This has a negligible probability if \p N
  *                 is significantly larger than \p min, which is the case
  *                 for all usual cryptographic applications.
  */
 int mbedtls_mpi_mod_raw_random(mbedtls_mpi_uint *X,
                                mbedtls_mpi_uint min,
                                const mbedtls_mpi_mod_modulus *N,
                                int (*f_rng)(void *, unsigned char *, size_t),
                                void *p_rng);

 /** Convert an MPI into Montgomery form.
  *
  * \param X      The address of the MPI.
  *               Must have the same number of limbs as \p N.
  * \param N      The address of the modulus, which gives the size of
  *               the base `R` = 2^(biL*N->limbs).
  *
  * \return       \c 0 if successful.
  */
 int mbedtls_mpi_mod_raw_to_mont_rep(mbedtls_mpi_uint *X,
                                     const mbedtls_mpi_mod_modulus *N);

 /** Convert an MPI back from Montgomery representation.
  *
  * \param X      The address of the MPI.
  *               Must have the same number of limbs as \p N.
  * \param N      The address of the modulus, which gives the size of
  *               the base `R`= 2^(biL*N->limbs).
  *
  * \return       \c 0 if successful.
  */
 int mbedtls_mpi_mod_raw_from_mont_rep(mbedtls_mpi_uint *X,
                                       const mbedtls_mpi_mod_modulus *N);

 /** \brief  Perform fixed width modular negation.
  *
  * The size of the operation is determined by \p N. \p A must have
  * the same number of limbs as \p N.
  *
  * \p X may be aliased to \p A.
  *
  * \param[out] X        The result of the modular negation.
  *                      This must be initialized.
  * \param[in] A         Little-endian presentation of the input operand. This
  *                      must be less than or equal to \p N.
  * \param[in] N         The modulus to use.
  */
 void mbedtls_mpi_mod_raw_neg(mbedtls_mpi_uint *X,
                              const mbedtls_mpi_uint *A,
                              const mbedtls_mpi_mod_modulus *N);

 #endif /* MBEDTLS_BIGNUM_MOD_RAW_H */
	/**
	* Low-level modular bignum functions
	*
	* This interface should only be used by the higher-level modular bignum
	* module (bignum_mod.c) and the ECP module (ecp.c, ecp_curves.c). All other
	* modules should use the high-level modular bignum interface (bignum_mod.h)
	* or the legacy bignum interface (bignum.h).
	*
	* This is a low-level interface to operations on integers modulo which
	* has no protection against passing invalid arguments such as arrays of
	* the wrong size. The functions in bignum_mod.h provide a higher-level
	* interface that includes protections against accidental misuse, at the
	* expense of code size and sometimes more cumbersome memory management.
	*
	* The functions in this module obey the following conventions unless
	* explicitly indicated otherwise:
	* - Modulus parameters: the modulus is passed as a pointer to a structure
	* of type #mbedtls_mpi_mod_modulus. The structure must be set up with an
	* array of limbs storing the bignum value of the modulus. The modulus must
	* be odd and is assumed to have no leading zeroes. The modulus is usually
	* named \c N and is usually input-only.
	* - Bignum parameters: Bignums are passed as pointers to an array of
	* limbs. A limb has the type #mbedtls_mpi_uint. Unless otherwise specified:
	* - Bignum parameters called \c A, \c B, ... are inputs, and are not
	* modified by the function.
	* - Bignum parameters called \c X, \c Y are outputs or input-output.
	* The initial content of output-only parameters is ignored.
	* - \c T is a temporary storage area. The initial content of such a
	* parameter is ignored and the final content is unspecified.
	* - Bignum sizes: bignum sizes are usually expressed by the \c limbs
	* member of the modulus argument. All bignum parameters must have the same
	* number of limbs as the modulus. All bignum sizes must be at least 1 and
	* must be significantly less than #SIZE_MAX. The behavior if a size is 0 is
	* undefined.
	* - Bignum representation: the representation of inputs and outputs is
	* specified by the \c int_rep field of the modulus for arithmetic
	* functions. Utility functions may allow for different representation.
	* - Parameter ordering: for bignum parameters, outputs come before inputs.
	* The modulus is passed after other bignum input parameters. Temporaries
	* come last.
	* - Aliasing: in general, output bignums may be aliased to one or more
	* inputs. Modulus values may not be aliased to any other parameter. Outputs
	* may not be aliased to one another. Temporaries may not be aliased to any
	* other parameter.
	* - Overlap: apart from aliasing of limb array pointers (where two
	* arguments are equal pointers), overlap is not supported and may result
	* in undefined behavior.
	* - Error handling: This is a low-level module. Functions generally do not
	* try to protect against invalid arguments such as nonsensical sizes or
	* null pointers. Note that passing bignums with a different size than the
	* modulus may lead to buffer overflows. Some functions which allocate
	* memory or handle reading/writing of bignums will return an error if
	* memory allocation fails or if buffer sizes are invalid.
	* - Modular representatives: all functions expect inputs to be in the
	* range [0, \c N - 1] and guarantee outputs in the range [0, \c N - 1]. If
	* an input is out of range, outputs are fully unspecified, though bignum
	* values out of range should not cause buffer overflows (beware that this is
	* not extensively tested).
	*/

	/*
	* Copyright The Mbed TLS Contributors
	* SPDX-License-Identifier: Apache-2.0 OR GPL-2.0-or-later
	*/

	#ifndef MBEDTLS_BIGNUM_MOD_RAW_H
	#define MBEDTLS_BIGNUM_MOD_RAW_H

	#include "common.h"

	#if defined(MBEDTLS_BIGNUM_C)
	#include "mbedtls/bignum.h"
	#endif

	#include "bignum_mod.h"

	/**
	* \brief Perform a safe conditional copy of an MPI which doesn't reveal
	* whether the assignment was done or not.
	*
	* The size to copy is determined by \p N.
	*
	* \param[out] X The address of the destination MPI.
	* This must be initialized. Must have enough limbs to
	* store the full value of \p A.
	* \param[in] A The address of the source MPI. This must be initialized.
	* \param[in] N The address of the modulus related to \p X and \p A.
	* \param assign The condition deciding whether to perform the
	* assignment or not. Must be either 0 or 1:
	* * \c 1: Perform the assignment `X = A`.
	* * \c 0: Keep the original value of \p X.
	*
	* \note This function avoids leaking any information about whether
	* the assignment was done or not.
	*
	* \warning If \p assign is neither 0 nor 1, the result of this function
	* is indeterminate, and the resulting value in \p X might be
	* neither its original value nor the value in \p A.
	*/
	void mbedtls_mpi_mod_raw_cond_assign(mbedtls_mpi_uint *X,
	const mbedtls_mpi_uint *A,
	const mbedtls_mpi_mod_modulus *N,
	unsigned char assign);

	/**
	* \brief Perform a safe conditional swap of two MPIs which doesn't reveal
	* whether the swap was done or not.
	*
	* The size to swap is determined by \p N.
	*
	* \param[in,out] X The address of the first MPI. This must be initialized.
	* \param[in,out] Y The address of the second MPI. This must be initialized.
	* \param[in] N The address of the modulus related to \p X and \p Y.
	* \param swap The condition deciding whether to perform
	* the swap or not. Must be either 0 or 1:
	* * \c 1: Swap the values of \p X and \p Y.
	* * \c 0: Keep the original values of \p X and \p Y.
	*
	* \note This function avoids leaking any information about whether
	* the swap was done or not.
	*
	* \warning If \p swap is neither 0 nor 1, the result of this function
	* is indeterminate, and both \p X and \p Y might end up with
	* values different to either of the original ones.
	*/
	void mbedtls_mpi_mod_raw_cond_swap(mbedtls_mpi_uint *X,
	mbedtls_mpi_uint *Y,
	const mbedtls_mpi_mod_modulus *N,
	unsigned char swap);

	/** Import X from unsigned binary data.
	*
	* The MPI needs to have enough limbs to store the full value (including any
	* most significant zero bytes in the input).
	*
	* \param[out] X The address of the MPI. The size is determined by \p N.
	* (In particular, it must have at least as many limbs as
	* the modulus \p N.)
	* \param[in] N The address of the modulus related to \p X.
	* \param[in] input The input buffer to import from.
	* \param input_length The length in bytes of \p input.
	* \param ext_rep The endianness of the number in the input buffer.
	*
	* \return \c 0 if successful.
	* \return #MBEDTLS_ERR_MPI_BUFFER_TOO_SMALL if \p X isn't
	* large enough to hold the value in \p input.
	* \return #MBEDTLS_ERR_MPI_BAD_INPUT_DATA if the external representation
	* of \p N is invalid or \p X is not less than \p N.
	*/
	int mbedtls_mpi_mod_raw_read(mbedtls_mpi_uint *X,
	const mbedtls_mpi_mod_modulus *N,
	const unsigned char *input,
	size_t input_length,
	mbedtls_mpi_mod_ext_rep ext_rep);

	/** Export A into unsigned binary data.
	*
	* \param[in] A The address of the MPI. The size is determined by \p N.
	* (In particular, it must have at least as many limbs as
	* the modulus \p N.)
	* \param[in] N The address of the modulus related to \p A.
	* \param[out] output The output buffer to export to.
	* \param output_length The length in bytes of \p output.
	* \param ext_rep The endianness in which the number should be written into the output buffer.
	*
	* \return \c 0 if successful.
	* \return #MBEDTLS_ERR_MPI_BUFFER_TOO_SMALL if \p output isn't
	* large enough to hold the value of \p A.
	* \return #MBEDTLS_ERR_MPI_BAD_INPUT_DATA if the external representation
	* of \p N is invalid.
	*/
	int mbedtls_mpi_mod_raw_write(const mbedtls_mpi_uint *A,
	const mbedtls_mpi_mod_modulus *N,
	unsigned char *output,
	size_t output_length,
	mbedtls_mpi_mod_ext_rep ext_rep);

	/** \brief Subtract two MPIs, returning the residue modulo the specified
	* modulus.
	*
	* The size of the operation is determined by \p N. \p A and \p B must have
	* the same number of limbs as \p N.
	*
	* \p X may be aliased to \p A or \p B, or even both, but may not overlap
	* either otherwise.
	*
	* \param[out] X The address of the result MPI.
	* This must be initialized. Must have enough limbs to
	* store the full value of the result.
	* \param[in] A The address of the first MPI. This must be initialized.
	* \param[in] B The address of the second MPI. This must be initialized.
	* \param[in] N The address of the modulus. Used to perform a modulo
	* operation on the result of the subtraction.
	*/
	void mbedtls_mpi_mod_raw_sub(mbedtls_mpi_uint *X,
	const mbedtls_mpi_uint *A,
	const mbedtls_mpi_uint *B,
	const mbedtls_mpi_mod_modulus *N);

	/** \brief Multiply two MPIs, returning the residue modulo the specified
	* modulus.
	*
	* \note Currently handles the case when `N->int_rep` is
	* MBEDTLS_MPI_MOD_REP_MONTGOMERY.
	*
	* The size of the operation is determined by \p N. \p A, \p B and \p X must
	* all be associated with the modulus \p N and must all have the same number
	* of limbs as \p N.
	*
	* \p X may be aliased to \p A or \p B, or even both, but may not overlap
	* either otherwise. They may not alias \p N (since they must be in canonical
	* form, they cannot == \p N).
	*
	* \param[out] X The address of the result MPI. Must have the same
	* number of limbs as \p N.
	* On successful completion, \p X contains the result of
	* the multiplication `A * B * R^-1` mod N where
	* `R = 2^(biL * N->limbs)`.
	* \param[in] A The address of the first MPI.
	* \param[in] B The address of the second MPI.
	* \param[in] N The address of the modulus. Used to perform a modulo
	* operation on the result of the multiplication.
	* \param[in,out] T Temporary storage of size at least 2 * N->limbs + 1
	* limbs. Its initial content is unused and
	* its final content is indeterminate.
	* It must not alias or otherwise overlap any of the
	* other parameters.
	*/
	void mbedtls_mpi_mod_raw_mul(mbedtls_mpi_uint *X,
	const mbedtls_mpi_uint *A,
	const mbedtls_mpi_uint *B,
	const mbedtls_mpi_mod_modulus *N,
	mbedtls_mpi_uint *T);

	/**
	* \brief Returns the number of limbs of working memory required for
	* a call to `mbedtls_mpi_mod_raw_inv_prime()`.
	*
	* \note This will always be at least
	* `mbedtls_mpi_core_montmul_working_limbs(AN_limbs)`,
	* i.e. sufficient for a call to `mbedtls_mpi_core_montmul()`.
	*
	* \param AN_limbs The number of limbs in the input `A` and the modulus `N`
	* (they must be the same size) that will be given to
	* `mbedtls_mpi_mod_raw_inv_prime()`.
	*
	* \return The number of limbs of working memory required by
	* `mbedtls_mpi_mod_raw_inv_prime()`.
	*/
	size_t mbedtls_mpi_mod_raw_inv_prime_working_limbs(size_t AN_limbs);

	/**
	* \brief Perform fixed-width modular inversion of a Montgomery-form MPI with
	* respect to a modulus \p N that must be prime.
	*
	* \p X may be aliased to \p A, but not to \p N or \p RR.
	*
	* \param[out] X The modular inverse of \p A with respect to \p N.
	* Will be in Montgomery form.
	* \param[in] A The number to calculate the modular inverse of.
	* Must be in Montgomery form. Must not be 0.
	* \param[in] N The modulus, as a little-endian array of length \p AN_limbs.
	* Must be prime.
	* \param AN_limbs The number of limbs in \p A, \p N and \p RR.
	* \param[in] RR The precomputed residue of 2^{2*biL} modulo N, as a little-
	* endian array of length \p AN_limbs.
	* \param[in,out] T Temporary storage of at least the number of limbs returned
	* by `mbedtls_mpi_mod_raw_inv_prime_working_limbs()`.
	* Its initial content is unused and its final content is
	* indeterminate.
	* It must not alias or otherwise overlap any of the other
	* parameters.
	* It is up to the caller to zeroize \p T when it is no
	* longer needed, and before freeing it if it was dynamically
	* allocated.
	*/
	void mbedtls_mpi_mod_raw_inv_prime(mbedtls_mpi_uint *X,
	const mbedtls_mpi_uint *A,
	const mbedtls_mpi_uint *N,
	size_t AN_limbs,
	const mbedtls_mpi_uint *RR,
	mbedtls_mpi_uint *T);

	/**
	* \brief Perform a known-size modular addition.
	*
	* Calculate `A + B modulo N`.
	*
	* The number of limbs in each operand, and the result, is given by the
	* modulus \p N.
	*
	* \p X may be aliased to \p A or \p B, or even both, but may not overlap
	* either otherwise.
	*
	* \param[out] X The result of the modular addition.
	* \param[in] A Little-endian presentation of the left operand. This
	* must be smaller than \p N.
	* \param[in] B Little-endian presentation of the right operand. This
	* must be smaller than \p N.
	* \param[in] N The address of the modulus.
	*/
	void mbedtls_mpi_mod_raw_add(mbedtls_mpi_uint *X,
	const mbedtls_mpi_uint *A,
	const mbedtls_mpi_uint *B,
	const mbedtls_mpi_mod_modulus *N);

	/** Convert an MPI from canonical representation (little-endian limb array)
	* to the representation associated with the modulus.
	*
	* \param[in,out] X The limb array to convert.
	* It must have as many limbs as \p N.
	* It is converted in place.
	* If this function returns an error, the content of \p X
	* is unspecified.
	* \param[in] N The modulus structure.
	*
	* \return \c 0 if successful.
	* Otherwise an \c MBEDTLS_ERR_MPI_xxx error code.
	*/
	int mbedtls_mpi_mod_raw_canonical_to_modulus_rep(
	mbedtls_mpi_uint *X,
	const mbedtls_mpi_mod_modulus *N);

	/** Convert an MPI from the representation associated with the modulus
	* to canonical representation (little-endian limb array).
	*
	* \param[in,out] X The limb array to convert.
	* It must have as many limbs as \p N.
	* It is converted in place.
	* If this function returns an error, the content of \p X
	* is unspecified.
	* \param[in] N The modulus structure.
	*
	* \return \c 0 if successful.
	* Otherwise an \c MBEDTLS_ERR_MPI_xxx error code.
	*/
	int mbedtls_mpi_mod_raw_modulus_to_canonical_rep(
	mbedtls_mpi_uint *X,
	const mbedtls_mpi_mod_modulus *N);

	/** Generate a random number uniformly in a range.
	*
	* This function generates a random number between \p min inclusive and
	* \p N exclusive.
	*
	* The procedure complies with RFC 6979 §3.3 (deterministic ECDSA)
	* when the RNG is a suitably parametrized instance of HMAC_DRBG
	* and \p min is \c 1.
	*
	* \note There are `N - min` possible outputs. The lower bound
	* \p min can be reached, but the upper bound \p N cannot.
	*
	* \param X The destination MPI, in canonical representation modulo \p N.
	* It must not be aliased with \p N or otherwise overlap it.
	* \param min The minimum value to return. It must be strictly smaller
	* than \b N.
	* \param N The modulus.
	* This is the upper bound of the output range, exclusive.
	* \param f_rng The RNG function to use. This must not be \c NULL.
	* \param p_rng The RNG parameter to be passed to \p f_rng.
	*
	* \return \c 0 if successful.
	* \return #MBEDTLS_ERR_MPI_NOT_ACCEPTABLE if the implementation was
	* unable to find a suitable value within a limited number
	* of attempts. This has a negligible probability if \p N
	* is significantly larger than \p min, which is the case
	* for all usual cryptographic applications.
	*/
	int mbedtls_mpi_mod_raw_random(mbedtls_mpi_uint *X,
	mbedtls_mpi_uint min,
	const mbedtls_mpi_mod_modulus *N,
	int (f_rng)(void , unsigned char *, size_t),
	void *p_rng);

	/** Convert an MPI into Montgomery form.
	*
	* \param X The address of the MPI.
	* Must have the same number of limbs as \p N.
	* \param N The address of the modulus, which gives the size of
	* the base `R` = 2^(biL*N->limbs).
	*
	* \return \c 0 if successful.
	*/
	int mbedtls_mpi_mod_raw_to_mont_rep(mbedtls_mpi_uint *X,
	const mbedtls_mpi_mod_modulus *N);

	/** Convert an MPI back from Montgomery representation.
	*
	* \param X The address of the MPI.
	* Must have the same number of limbs as \p N.
	* \param N The address of the modulus, which gives the size of
	* the base `R`= 2^(biL*N->limbs).
	*
	* \return \c 0 if successful.
	*/
	int mbedtls_mpi_mod_raw_from_mont_rep(mbedtls_mpi_uint *X,
	const mbedtls_mpi_mod_modulus *N);

	/** \brief Perform fixed width modular negation.
	*
	* The size of the operation is determined by \p N. \p A must have
	* the same number of limbs as \p N.
	*
	* \p X may be aliased to \p A.
	*
	* \param[out] X The result of the modular negation.
	* This must be initialized.
	* \param[in] A Little-endian presentation of the input operand. This
	* must be less than or equal to \p N.
	* \param[in] N The modulus to use.
	*/
	void mbedtls_mpi_mod_raw_neg(mbedtls_mpi_uint *X,
	const mbedtls_mpi_uint *A,
	const mbedtls_mpi_mod_modulus *N);

	#endif /* MBEDTLS_BIGNUM_MOD_RAW_H */