MastersThesis/PQ_TIIGER_TLS/sal/miracl-ubuntu22-11-04-24/includes/fp48_BLS48581.h

/*
 * Copyright (c) 2012-2020 MIRACL UK Ltd.
 *
 * This file is part of MIRACL Core
 * (see https://github.com/miracl/core).
 *
 * Licensed under the Apache License, Version 2.0 (the "License");
 * you may not use this file except in compliance with the License.
 * You may obtain a copy of the License at
 *
 *     http://www.apache.org/licenses/LICENSE-2.0
 *
 * Unless required by applicable law or agreed to in writing, software
 * distributed under the License is distributed on an "AS IS" BASIS,
 * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
 * See the License for the specific language governing permissions and
 * limitations under the License.
 */

#ifndef FP48_BLS48581_H
#define FP48_BLS48581_H

#include "fp16_BLS48581.h"

using namespace core;

namespace BLS48581 {
/**
	@brief FP12 Structure - towered over three FP16
*/

typedef struct
{
    FP16 a; /**< first part of FP12 */
    FP16 b; /**< second part of FP12 */
    FP16 c; /**< third part of FP12 */
    int type;
} FP48;

extern const B584_60::BIG Fra; /**< real part of BN curve Frobenius Constant */
extern const B584_60::BIG Frb; /**< imaginary part of BN curve Frobenius Constant */

/* FP48 prototypes */
/**	@brief Tests for FP48 equal to zero
 *
	@param x FP48 number to be tested
	@return 1 if zero, else returns 0
 */
extern int FP48_iszilch(FP48 *x);
/**	@brief Tests for FP48 equal to unity
 *
	@param x FP48 number to be tested
	@return 1 if unity, else returns 0
 */
extern int FP48_isunity(FP48 *x);
/**	@brief Copy FP48 to another FP48
 *
	@param x FP48 instance, on exit = y
	@param y FP48 instance to be copied
 */
extern void FP48_copy(FP48 *x, FP48 *y);
/**	@brief Set FP48 to unity
 *
	@param x FP48 instance to be set to one
 */
extern void FP48_one(FP48 *x);

/**	@brief Set FP48 to zero
 *
	@param x FP48 instance to be set to zero
 */
extern void FP48_zero(FP48 *x);

/**	@brief Tests for equality of two FP48s
 *
	@param x FP48 instance to be compared
	@param y FP48 instance to be compared
	@return 1 if x=y, else returns 0
 */
extern int FP48_equals(FP48 *x, FP48 *y);
/**	@brief Conjugation of FP48
 *
	If y=(a,b,c) (where a,b,c are its three FP16 components) on exit x=(conj(a),-conj(b),conj(c))
	@param x FP48 instance, on exit = conj(y)
	@param y FP48 instance
 */
extern void FP48_conj(FP48 *x, FP48 *y);
/**	@brief Initialise FP48 from single FP16
 *
	Sets first FP16 component of an FP48, other components set to zero
	@param x FP48 instance to be initialised
	@param a FP16 to form first part of FP48
 */
extern void FP48_from_FP16(FP48 *x, FP16 *a);
/**	@brief Initialise FP48 from three FP16s
 *
	@param x FP48 instance to be initialised
	@param a FP16 to form first part of FP48
	@param b FP16 to form second part of FP48
	@param c FP16 to form third part of FP48
 */
extern void FP48_from_FP16s(FP48 *x, FP16 *a, FP16* b, FP16 *c);
/**	@brief Fast Squaring of an FP48 in "unitary" form
 *
	@param x FP48 instance, on exit = y^2
	@param y FP16 instance, must be unitary
 */
extern void FP48_usqr(FP48 *x, FP48 *y);
/**	@brief Squaring an FP48
 *
	@param x FP48 instance, on exit = y^2
	@param y FP48 instance
 */
extern void FP48_sqr(FP48 *x, FP48 *y);
/**	@brief Fast multiplication of two sparse FP24s that arises from ATE pairing line functions
 *
	@param x FP48 instance, on exit = x*y
	@param y FP48 instance, of special form
 */
extern void FP48_smul(FP48 *x, FP48 *y);

/**	@brief Fast multiplication of what may be sparse multiplicands
 *
	@param x FP48 instance, on exit = x*y
	@param y FP48 instance, of special form
 */
extern void FP48_ssmul(FP48 *x, FP48 *y);
/**	@brief Full unconditional Multiplication of two FP24s
 *
	@param x FP48 instance, on exit = x*y
	@param y FP48 instance, the multiplier
 */
extern void FP48_mul(FP48 *x, FP48 *y);
/**	@brief Inverting an FP48
 *
	@param x FP48 instance, on exit = 1/y
	@param y FP48 instance
 */
extern void FP48_inv(FP48 *x, FP48 *y);
/**	@brief Raises an FP48 to the power of a BIG
 *
	@param r FP48 instance, on exit = y^b
	@param x FP48 instance
	@param b BIG number
 */
extern void FP48_pow(FP48 *r, FP48 *x, B584_60::BIG b);

//extern void FP48_ppow(FP48 *r,FP48 *x,B584_60::BIG b);

/**	@brief Raises an FP48 instance x to a small integer power, side-channel resistant
 *
	@param x FP48 instance, on exit = x^i
	@param i small integer exponent
	@param b maximum number of bits in exponent
 */
extern void FP48_pinpow(FP48 *x, int i, int b);

/**	@brief Raises an FP48 instance x to a BIG power, compressed to FP16
 *
	@param c FP16 instance, on exit = x^(e mod r) as FP16
	@param x FP48 input
	@param e BIG exponent
	@param r BIG group order
 */
extern void FP48_compow(FP16 *c, FP48 *x, B584_60::BIG e, B584_60::BIG r);

/**	@brief Calculate Pi x[i]^b[i] for i=0 to 15, side-channel resistant
 *
	@param r FP48 instance, on exit = Pi x[i]^b[i] for i=0 to 15
	@param x FP48 array with 16 FP48s
	@param b BIG array of 16 exponents
 */
extern void FP48_pow16(FP48 *r, FP48 *x, B584_60::BIG *b);


/**	@brief Raises an FP48 to the power of the internal modulus p, using the Frobenius
 *
	@param x FP48 instance, on exit = x^p^n
	@param f FP2 precalculated Frobenius constant
	@param n power of p
 */
extern void FP48_frob(FP48 *x, FP2 *f, int n);

/**	@brief Reduces all components of possibly unreduced FP48 mod Modulus
 *
	@param x FP48 instance, on exit reduced mod Modulus
 */
extern void FP48_reduce(FP48 *x);
/**	@brief Normalises the components of an FP48
 *
	@param x FP48 instance to be normalised
 */
extern void FP48_norm(FP48 *x);
/**	@brief Formats and outputs an FP48 to the console
 *
	@param x FP48 instance to be printed
 */
extern void FP48_output(FP48 *x);
/**	@brief Formats and outputs an FP48 instance to an octet string
 *
	Serializes the components of an FP48 to big-endian base 256 form.
	@param S output octet string
	@param x FP48 instance to be converted to an octet string
 */
extern void FP48_toOctet(octet *S, FP48 *x);
/**	@brief Creates an FP48 instance from an octet string
 *
	De-serializes the components of an FP48 to create an FP48 from big-endian base 256 components.
	@param x FP48 instance to be created from an octet string
	@param S input octet string

 */
extern void FP48_fromOctet(FP48 *x, octet *S);
/**	@brief Calculate the trace of an FP48
 *
	@param t FP16 trace of x, on exit = tr(x)
	@param x FP48 instance

 */
extern void FP48_trace(FP16 *t, FP48 *x);

/**	@brief Conditional copy of FP48 number
 *
	Conditionally copies second parameter to the first (without branching)
	@param x FP48 instance, set to y if s!=0
	@param y another FP48 instance
	@param s copy only takes place if not equal to 0
 */
extern void FP48_cmove(FP48 *x, FP48 *y, int s);
}
#endif
update tiigertls 2024-04-15 09:53:30 +00:00			`/*`
			`* Copyright (c) 2012-2020 MIRACL UK Ltd.`
			`*`
			`* This file is part of MIRACL Core`
			`* (see https://github.com/miracl/core).`
			`*`
			`* Licensed under the Apache License, Version 2.0 (the "License");`
			`* you may not use this file except in compliance with the License.`
			`* You may obtain a copy of the License at`
			`*`
			`* http://www.apache.org/licenses/LICENSE-2.0`
			`*`
			`* Unless required by applicable law or agreed to in writing, software`
			`* distributed under the License is distributed on an "AS IS" BASIS,`
			`* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.`
			`* See the License for the specific language governing permissions and`
			`* limitations under the License.`
			`*/`

			`#ifndef FP48_BLS48581_H`
			`#define FP48_BLS48581_H`

			`#include "fp16_BLS48581.h"`

			`using namespace core;`

			`namespace BLS48581 {`
			`/**`
			`@brief FP12 Structure - towered over three FP16`
			`*/`

			`typedef struct`
			`{`
			`FP16 a; /*< first part of FP12 /`
			`FP16 b; /*< second part of FP12 /`
			`FP16 c; /*< third part of FP12 /`
			`int type;`
			`} FP48;`

			`extern const B584_60::BIG Fra; /*< real part of BN curve Frobenius Constant /`
			`extern const B584_60::BIG Frb; /*< imaginary part of BN curve Frobenius Constant /`

			`/* FP48 prototypes */`
			`/** @brief Tests for FP48 equal to zero`
			`*`
			`@param x FP48 number to be tested`
			`@return 1 if zero, else returns 0`
			`*/`
			`extern int FP48_iszilch(FP48 *x);`
			`/** @brief Tests for FP48 equal to unity`
			`*`
			`@param x FP48 number to be tested`
			`@return 1 if unity, else returns 0`
			`*/`
			`extern int FP48_isunity(FP48 *x);`
			`/** @brief Copy FP48 to another FP48`
			`*`
			`@param x FP48 instance, on exit = y`
			`@param y FP48 instance to be copied`
			`*/`
			`extern void FP48_copy(FP48 x, FP48 y);`
			`/** @brief Set FP48 to unity`
			`*`
			`@param x FP48 instance to be set to one`
			`*/`
			`extern void FP48_one(FP48 *x);`

			`/** @brief Set FP48 to zero`
			`*`
			`@param x FP48 instance to be set to zero`
			`*/`
			`extern void FP48_zero(FP48 *x);`

			`/** @brief Tests for equality of two FP48s`
			`*`
			`@param x FP48 instance to be compared`
			`@param y FP48 instance to be compared`
			`@return 1 if x=y, else returns 0`
			`*/`
			`extern int FP48_equals(FP48 x, FP48 y);`
			`/** @brief Conjugation of FP48`
			`*`
			`If y=(a,b,c) (where a,b,c are its three FP16 components) on exit x=(conj(a),-conj(b),conj(c))`
			`@param x FP48 instance, on exit = conj(y)`
			`@param y FP48 instance`
			`*/`
			`extern void FP48_conj(FP48 x, FP48 y);`
			`/** @brief Initialise FP48 from single FP16`
			`*`
			`Sets first FP16 component of an FP48, other components set to zero`
			`@param x FP48 instance to be initialised`
			`@param a FP16 to form first part of FP48`
			`*/`
			`extern void FP48_from_FP16(FP48 x, FP16 a);`
			`/** @brief Initialise FP48 from three FP16s`
			`*`
			`@param x FP48 instance to be initialised`
			`@param a FP16 to form first part of FP48`
			`@param b FP16 to form second part of FP48`
			`@param c FP16 to form third part of FP48`
			`*/`
			`extern void FP48_from_FP16s(FP48 x, FP16 a, FP16* b, FP16 *c);`
			`/** @brief Fast Squaring of an FP48 in "unitary" form`
			`*`
			`@param x FP48 instance, on exit = y^2`
			`@param y FP16 instance, must be unitary`
			`*/`
			`extern void FP48_usqr(FP48 x, FP48 y);`
			`/** @brief Squaring an FP48`
			`*`
			`@param x FP48 instance, on exit = y^2`
			`@param y FP48 instance`
			`*/`
			`extern void FP48_sqr(FP48 x, FP48 y);`
			`/** @brief Fast multiplication of two sparse FP24s that arises from ATE pairing line functions`
			`*`
			`@param x FP48 instance, on exit = x*y`
			`@param y FP48 instance, of special form`
			`*/`
			`extern void FP48_smul(FP48 x, FP48 y);`

			`/** @brief Fast multiplication of what may be sparse multiplicands`
			`*`
			`@param x FP48 instance, on exit = x*y`
			`@param y FP48 instance, of special form`
			`*/`
			`extern void FP48_ssmul(FP48 x, FP48 y);`
			`/** @brief Full unconditional Multiplication of two FP24s`
			`*`
			`@param x FP48 instance, on exit = x*y`
			`@param y FP48 instance, the multiplier`
			`*/`
			`extern void FP48_mul(FP48 x, FP48 y);`
			`/** @brief Inverting an FP48`
			`*`
			`@param x FP48 instance, on exit = 1/y`
			`@param y FP48 instance`
			`*/`
			`extern void FP48_inv(FP48 x, FP48 y);`
			`/** @brief Raises an FP48 to the power of a BIG`
			`*`
			`@param r FP48 instance, on exit = y^b`
			`@param x FP48 instance`
			`@param b BIG number`
			`*/`
			`extern void FP48_pow(FP48 r, FP48 x, B584_60::BIG b);`

			`//extern void FP48_ppow(FP48 r,FP48 x,B584_60::BIG b);`

			`/** @brief Raises an FP48 instance x to a small integer power, side-channel resistant`
			`*`
			`@param x FP48 instance, on exit = x^i`
			`@param i small integer exponent`
			`@param b maximum number of bits in exponent`
			`*/`
			`extern void FP48_pinpow(FP48 *x, int i, int b);`

			`/** @brief Raises an FP48 instance x to a BIG power, compressed to FP16`
			`*`
			`@param c FP16 instance, on exit = x^(e mod r) as FP16`
			`@param x FP48 input`
			`@param e BIG exponent`
			`@param r BIG group order`
			`*/`
			`extern void FP48_compow(FP16 c, FP48 x, B584_60::BIG e, B584_60::BIG r);`

			`/** @brief Calculate Pi x[i]^b[i] for i=0 to 15, side-channel resistant`
			`*`
			`@param r FP48 instance, on exit = Pi x[i]^b[i] for i=0 to 15`
			`@param x FP48 array with 16 FP48s`
			`@param b BIG array of 16 exponents`
			`*/`
			`extern void FP48_pow16(FP48 r, FP48 x, B584_60::BIG *b);`


			`/** @brief Raises an FP48 to the power of the internal modulus p, using the Frobenius`
			`*`
			`@param x FP48 instance, on exit = x^p^n`
			`@param f FP2 precalculated Frobenius constant`
			`@param n power of p`
			`*/`
			`extern void FP48_frob(FP48 x, FP2 f, int n);`

			`/** @brief Reduces all components of possibly unreduced FP48 mod Modulus`
			`*`
			`@param x FP48 instance, on exit reduced mod Modulus`
			`*/`
			`extern void FP48_reduce(FP48 *x);`
			`/** @brief Normalises the components of an FP48`
			`*`
			`@param x FP48 instance to be normalised`
			`*/`
			`extern void FP48_norm(FP48 *x);`
			`/** @brief Formats and outputs an FP48 to the console`
			`*`
			`@param x FP48 instance to be printed`
			`*/`
			`extern void FP48_output(FP48 *x);`
			`/** @brief Formats and outputs an FP48 instance to an octet string`
			`*`
			`Serializes the components of an FP48 to big-endian base 256 form.`
			`@param S output octet string`
			`@param x FP48 instance to be converted to an octet string`
			`*/`
			`extern void FP48_toOctet(octet S, FP48 x);`
			`/** @brief Creates an FP48 instance from an octet string`
			`*`
			`De-serializes the components of an FP48 to create an FP48 from big-endian base 256 components.`
			`@param x FP48 instance to be created from an octet string`
			`@param S input octet string`

			`*/`
			`extern void FP48_fromOctet(FP48 x, octet S);`
			`/** @brief Calculate the trace of an FP48`
			`*`
			`@param t FP16 trace of x, on exit = tr(x)`
			`@param x FP48 instance`

			`*/`
			`extern void FP48_trace(FP16 t, FP48 x);`

			`/** @brief Conditional copy of FP48 number`
			`*`
			`Conditionally copies second parameter to the first (without branching)`
			`@param x FP48 instance, set to y if s!=0`
			`@param y another FP48 instance`
			`@param s copy only takes place if not equal to 0`
			`*/`
			`extern void FP48_cmove(FP48 x, FP48 y, int s);`
			`}`
			`#endif`