src/libsystemd/sd-journal/fsprg.c - systemd - Git at Google

 /* SPDX-License-Identifier: LGPL-2.1-or-later
  *
  * fsprg v0.1  -  (seekable) forward-secure pseudorandom generator
  * Copyright © 2012 B. Poettering
  * Contact: fsprg@point-at-infinity.org
  *
  * This library is free software; you can redistribute it and/or
  * modify it under the terms of the GNU Lesser General Public
  * License as published by the Free Software Foundation; either
  * version 2.1 of the License, or (at your option) any later version.
  *
  * This library 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
  * Lesser General Public License for more details.
  *
  * You should have received a copy of the GNU Lesser General Public
  * License along with this library; if not, write to the Free Software
  * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA
  * 02110-1301  USA
  */

 /*
  * See "Practical Secure Logging: Seekable Sequential Key Generators"
  * by G. A. Marson, B. Poettering for details:
  *
  * http://eprint.iacr.org/2013/397
  */

 #include <string.h>

 #include "fsprg.h"
 #include "gcrypt-util.h"
 #include "memory-util.h"

 #define ISVALID_SECPAR(secpar) (((secpar) % 16 == 0) && ((secpar) >= 16) && ((secpar) <= 16384))
 #define VALIDATE_SECPAR(secpar) assert(ISVALID_SECPAR(secpar));

 #define RND_HASH GCRY_MD_SHA256
 #define RND_GEN_P 0x01
 #define RND_GEN_Q 0x02
 #define RND_GEN_X 0x03

 #pragma GCC diagnostic ignored "-Wpointer-arith"
 /* TODO: remove void* arithmetic and this work-around */

 /******************************************************************************/

 static void mpi_export(void *buf, size_t buflen, const gcry_mpi_t x) {
         unsigned len;
         size_t nwritten;

         assert(gcry_mpi_cmp_ui(x, 0) >= 0);
         len = (gcry_mpi_get_nbits(x) + 7) / 8;
         assert(len <= buflen);
         memzero(buf, buflen);
         gcry_mpi_print(GCRYMPI_FMT_USG, buf + (buflen - len), len, &nwritten, x);
         assert(nwritten == len);
 }

 static gcry_mpi_t mpi_import(const void *buf, size_t buflen) {
         gcry_mpi_t h;
         _unused_ unsigned len;

         assert_se(gcry_mpi_scan(&h, GCRYMPI_FMT_USG, buf, buflen, NULL) == 0);
         len = (gcry_mpi_get_nbits(h) + 7) / 8;
         assert(len <= buflen);
         assert(gcry_mpi_cmp_ui(h, 0) >= 0);

         return h;
 }

 static void uint64_export(void *buf, size_t buflen, uint64_t x) {
         assert(buflen == 8);
         ((uint8_t*) buf)[0] = (x >> 56) & 0xff;
         ((uint8_t*) buf)[1] = (x >> 48) & 0xff;
         ((uint8_t*) buf)[2] = (x >> 40) & 0xff;
         ((uint8_t*) buf)[3] = (x >> 32) & 0xff;
         ((uint8_t*) buf)[4] = (x >> 24) & 0xff;
         ((uint8_t*) buf)[5] = (x >> 16) & 0xff;
         ((uint8_t*) buf)[6] = (x >>  8) & 0xff;
         ((uint8_t*) buf)[7] = (x >>  0) & 0xff;
 }

 _pure_ static uint64_t uint64_import(const void *buf, size_t buflen) {
         assert(buflen == 8);
         return
                 (uint64_t)(((uint8_t*) buf)[0]) << 56 |
                 (uint64_t)(((uint8_t*) buf)[1]) << 48 |
                 (uint64_t)(((uint8_t*) buf)[2]) << 40 |
                 (uint64_t)(((uint8_t*) buf)[3]) << 32 |
                 (uint64_t)(((uint8_t*) buf)[4]) << 24 |
                 (uint64_t)(((uint8_t*) buf)[5]) << 16 |
                 (uint64_t)(((uint8_t*) buf)[6]) <<  8 |
                 (uint64_t)(((uint8_t*) buf)[7]) <<  0;
 }

 /* deterministically generate from seed/idx a string of buflen pseudorandom bytes */
 static void det_randomize(void *buf, size_t buflen, const void *seed, size_t seedlen, uint32_t idx) {
         gcry_md_hd_t hd, hd2;
         size_t olen, cpylen;
         gcry_error_t err;
         uint32_t ctr;

         olen = gcry_md_get_algo_dlen(RND_HASH);
         err = gcry_md_open(&hd, RND_HASH, 0);
         assert_se(gcry_err_code(err) == GPG_ERR_NO_ERROR); /* This shouldn't happen */
         gcry_md_write(hd, seed, seedlen);
         gcry_md_putc(hd, (idx >> 24) & 0xff);
         gcry_md_putc(hd, (idx >> 16) & 0xff);
         gcry_md_putc(hd, (idx >>  8) & 0xff);
         gcry_md_putc(hd, (idx >>  0) & 0xff);

         for (ctr = 0; buflen; ctr++) {
                 err = gcry_md_copy(&hd2, hd);
                 assert_se(gcry_err_code(err) == GPG_ERR_NO_ERROR); /* This shouldn't happen */
                 gcry_md_putc(hd2, (ctr >> 24) & 0xff);
                 gcry_md_putc(hd2, (ctr >> 16) & 0xff);
                 gcry_md_putc(hd2, (ctr >>  8) & 0xff);
                 gcry_md_putc(hd2, (ctr >>  0) & 0xff);
                 gcry_md_final(hd2);
                 cpylen = (buflen < olen) ? buflen : olen;
                 memcpy(buf, gcry_md_read(hd2, RND_HASH), cpylen);
                 gcry_md_close(hd2);
                 buf += cpylen;
                 buflen -= cpylen;
         }
         gcry_md_close(hd);
 }

 /* deterministically generate from seed/idx a prime of length `bits' that is 3 (mod 4) */
 static gcry_mpi_t genprime3mod4(int bits, const void *seed, size_t seedlen, uint32_t idx) {
         size_t buflen = bits / 8;
         uint8_t buf[buflen];
         gcry_mpi_t p;

         assert(bits % 8 == 0);
         assert(buflen > 0);

         det_randomize(buf, buflen, seed, seedlen, idx);
         buf[0] |= 0xc0; /* set upper two bits, so that n=pq has maximum size */
         buf[buflen - 1] |= 0x03; /* set lower two bits, to have result 3 (mod 4) */

         p = mpi_import(buf, buflen);
         while (gcry_prime_check(p, 0))
                 gcry_mpi_add_ui(p, p, 4);

         return p;
 }

 /* deterministically generate from seed/idx a quadratic residue (mod n) */
 static gcry_mpi_t gensquare(const gcry_mpi_t n, const void *seed, size_t seedlen, uint32_t idx, unsigned secpar) {
         size_t buflen = secpar / 8;
         uint8_t buf[buflen];
         gcry_mpi_t x;

         det_randomize(buf, buflen, seed, seedlen, idx);
         buf[0] &= 0x7f; /* clear upper bit, so that we have x < n */
         x = mpi_import(buf, buflen);
         assert(gcry_mpi_cmp(x, n) < 0);
         gcry_mpi_mulm(x, x, x, n);
         return x;
 }

 /* compute 2^m (mod phi(p)), for a prime p */
 static gcry_mpi_t twopowmodphi(uint64_t m, const gcry_mpi_t p) {
         gcry_mpi_t phi, r;
         int n;

         phi = gcry_mpi_new(0);
         gcry_mpi_sub_ui(phi, p, 1);

         /* count number of used bits in m */
         for (n = 0; (1ULL << n) <= m; n++)
                 ;

         r = gcry_mpi_new(0);
         gcry_mpi_set_ui(r, 1);
         while (n) { /* square and multiply algorithm for fast exponentiation */
                 n--;
                 gcry_mpi_mulm(r, r, r, phi);
                 if (m & ((uint64_t)1 << n)) {
                         gcry_mpi_add(r, r, r);
                         if (gcry_mpi_cmp(r, phi) >= 0)
                                 gcry_mpi_sub(r, r, phi);
                 }
         }

         gcry_mpi_release(phi);
         return r;
 }

 /* Decompose $x \in Z_n$ into $(xp,xq) \in Z_p \times Z_q$ using Chinese Remainder Theorem */
 static void CRT_decompose(gcry_mpi_t *xp, gcry_mpi_t *xq, const gcry_mpi_t x, const gcry_mpi_t p, const gcry_mpi_t q) {
         *xp = gcry_mpi_new(0);
         *xq = gcry_mpi_new(0);
         gcry_mpi_mod(*xp, x, p);
         gcry_mpi_mod(*xq, x, q);
 }

 /* Compose $(xp,xq) \in Z_p \times Z_q$ into $x \in Z_n$ using Chinese Remainder Theorem */
 static void CRT_compose(gcry_mpi_t *x, const gcry_mpi_t xp, const gcry_mpi_t xq, const gcry_mpi_t p, const gcry_mpi_t q) {
         gcry_mpi_t a, u;

         a = gcry_mpi_new(0);
         u = gcry_mpi_new(0);
         *x = gcry_mpi_new(0);
         gcry_mpi_subm(a, xq, xp, q);
         gcry_mpi_invm(u, p, q);
         gcry_mpi_mulm(a, a, u, q); /* a = (xq - xp) / p  (mod q) */
         gcry_mpi_mul(*x, p, a);
         gcry_mpi_add(*x, *x, xp); /* x = p * ((xq - xp) / p mod q) + xp */
         gcry_mpi_release(a);
         gcry_mpi_release(u);
 }

 /******************************************************************************/

 size_t FSPRG_mskinbytes(unsigned _secpar) {
         VALIDATE_SECPAR(_secpar);
         return 2 + 2 * (_secpar / 2) / 8; /* to store header,p,q */
 }

 size_t FSPRG_mpkinbytes(unsigned _secpar) {
         VALIDATE_SECPAR(_secpar);
         return 2 + _secpar / 8; /* to store header,n */
 }

 size_t FSPRG_stateinbytes(unsigned _secpar) {
         VALIDATE_SECPAR(_secpar);
         return 2 + 2 * _secpar / 8 + 8; /* to store header,n,x,epoch */
 }

 static void store_secpar(void *buf, uint16_t secpar) {
         secpar = secpar / 16 - 1;
         ((uint8_t*) buf)[0] = (secpar >> 8) & 0xff;
         ((uint8_t*) buf)[1] = (secpar >> 0) & 0xff;
 }

 static uint16_t read_secpar(const void *buf) {
         uint16_t secpar;
         secpar =
                 (uint16_t)(((uint8_t*) buf)[0]) << 8 |
                 (uint16_t)(((uint8_t*) buf)[1]) << 0;
         return 16 * (secpar + 1);
 }

 void FSPRG_GenMK(void *msk, void *mpk, const void *seed, size_t seedlen, unsigned _secpar) {
         uint8_t iseed[FSPRG_RECOMMENDED_SEEDLEN];
         gcry_mpi_t n, p, q;
         uint16_t secpar;

         VALIDATE_SECPAR(_secpar);
         secpar = _secpar;

         initialize_libgcrypt(false);

         if (!seed) {
                 gcry_randomize(iseed, FSPRG_RECOMMENDED_SEEDLEN, GCRY_STRONG_RANDOM);
                 seed = iseed;
                 seedlen = FSPRG_RECOMMENDED_SEEDLEN;
         }

         p = genprime3mod4(secpar / 2, seed, seedlen, RND_GEN_P);
         q = genprime3mod4(secpar / 2, seed, seedlen, RND_GEN_Q);

         if (msk) {
                 store_secpar(msk + 0, secpar);
                 mpi_export(msk + 2 + 0 * (secpar / 2) / 8, (secpar / 2) / 8, p);
                 mpi_export(msk + 2 + 1 * (secpar / 2) / 8, (secpar / 2) / 8, q);
         }

         if (mpk) {
                 n = gcry_mpi_new(0);
                 gcry_mpi_mul(n, p, q);
                 assert(gcry_mpi_get_nbits(n) == secpar);

                 store_secpar(mpk + 0, secpar);
                 mpi_export(mpk + 2, secpar / 8, n);

                 gcry_mpi_release(n);
         }

         gcry_mpi_release(p);
         gcry_mpi_release(q);
 }

 void FSPRG_GenState0(void *state, const void *mpk, const void *seed, size_t seedlen) {
         gcry_mpi_t n, x;
         uint16_t secpar;

         initialize_libgcrypt(false);

         secpar = read_secpar(mpk + 0);
         n = mpi_import(mpk + 2, secpar / 8);
         x = gensquare(n, seed, seedlen, RND_GEN_X, secpar);

         memcpy(state, mpk, 2 + secpar / 8);
         mpi_export(state + 2 + 1 * secpar / 8, secpar / 8, x);
         memzero(state + 2 + 2 * secpar / 8, 8);

         gcry_mpi_release(n);
         gcry_mpi_release(x);
 }

 void FSPRG_Evolve(void *state) {
         gcry_mpi_t n, x;
         uint16_t secpar;
         uint64_t epoch;

         initialize_libgcrypt(false);

         secpar = read_secpar(state + 0);
         n = mpi_import(state + 2 + 0 * secpar / 8, secpar / 8);
         x = mpi_import(state + 2 + 1 * secpar / 8, secpar / 8);
         epoch = uint64_import(state + 2 + 2 * secpar / 8, 8);

         gcry_mpi_mulm(x, x, x, n);
         epoch++;

         mpi_export(state + 2 + 1 * secpar / 8, secpar / 8, x);
         uint64_export(state + 2 + 2 * secpar / 8, 8, epoch);

         gcry_mpi_release(n);
         gcry_mpi_release(x);
 }

 uint64_t FSPRG_GetEpoch(const void *state) {
         uint16_t secpar;
         secpar = read_secpar(state + 0);
         return uint64_import(state + 2 + 2 * secpar / 8, 8);
 }

 void FSPRG_Seek(void *state, uint64_t epoch, const void *msk, const void *seed, size_t seedlen) {
         gcry_mpi_t p, q, n, x, xp, xq, kp, kq, xm;
         uint16_t secpar;

         initialize_libgcrypt(false);

         secpar = read_secpar(msk + 0);
         p  = mpi_import(msk + 2 + 0 * (secpar / 2) / 8, (secpar / 2) / 8);
         q  = mpi_import(msk + 2 + 1 * (secpar / 2) / 8, (secpar / 2) / 8);

         n = gcry_mpi_new(0);
         gcry_mpi_mul(n, p, q);

         x = gensquare(n, seed, seedlen, RND_GEN_X, secpar);
         CRT_decompose(&xp, &xq, x, p, q); /* split (mod n) into (mod p) and (mod q) using CRT */

         kp = twopowmodphi(epoch, p); /* compute 2^epoch (mod phi(p)) */
         kq = twopowmodphi(epoch, q); /* compute 2^epoch (mod phi(q)) */

         gcry_mpi_powm(xp, xp, kp, p); /* compute x^(2^epoch) (mod p) */
         gcry_mpi_powm(xq, xq, kq, q); /* compute x^(2^epoch) (mod q) */

         CRT_compose(&xm, xp, xq, p, q); /* combine (mod p) and (mod q) to (mod n) using CRT */

         store_secpar(state + 0, secpar);
         mpi_export(state + 2 + 0 * secpar / 8, secpar / 8, n);
         mpi_export(state + 2 + 1 * secpar / 8, secpar / 8, xm);
         uint64_export(state + 2 + 2 * secpar / 8, 8, epoch);

         gcry_mpi_release(p);
         gcry_mpi_release(q);
         gcry_mpi_release(n);
         gcry_mpi_release(x);
         gcry_mpi_release(xp);
         gcry_mpi_release(xq);
         gcry_mpi_release(kp);
         gcry_mpi_release(kq);
         gcry_mpi_release(xm);
 }

 void FSPRG_GetKey(const void *state, void *key, size_t keylen, uint32_t idx) {
         uint16_t secpar;

         initialize_libgcrypt(false);

         secpar = read_secpar(state + 0);
         det_randomize(key, keylen, state + 2, 2 * secpar / 8 + 8, idx);
 }
	/* SPDX-License-Identifier: LGPL-2.1-or-later
	*
	* fsprg v0.1 - (seekable) forward-secure pseudorandom generator
	* Copyright © 2012 B. Poettering
	* Contact: fsprg@point-at-infinity.org
	*
	* This library is free software; you can redistribute it and/or
	* modify it under the terms of the GNU Lesser General Public
	* License as published by the Free Software Foundation; either
	* version 2.1 of the License, or (at your option) any later version.
	*
	* This library 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
	* Lesser General Public License for more details.
	*
	* You should have received a copy of the GNU Lesser General Public
	* License along with this library; if not, write to the Free Software
	* Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA
	* 02110-1301 USA
	*/

	/*
	* See "Practical Secure Logging: Seekable Sequential Key Generators"
	* by G. A. Marson, B. Poettering for details:
	*
	* http://eprint.iacr.org/2013/397
	*/

	#include <string.h>

	#include "fsprg.h"
	#include "gcrypt-util.h"
	#include "memory-util.h"

	#define ISVALID_SECPAR(secpar) (((secpar) % 16 == 0) && ((secpar) >= 16) && ((secpar) <= 16384))
	#define VALIDATE_SECPAR(secpar) assert(ISVALID_SECPAR(secpar));

	#define RND_HASH GCRY_MD_SHA256
	#define RND_GEN_P 0x01
	#define RND_GEN_Q 0x02
	#define RND_GEN_X 0x03

	#pragma GCC diagnostic ignored "-Wpointer-arith"
	/* TODO: remove void* arithmetic and this work-around */

	/******************************************************************************/

	static void mpi_export(void *buf, size_t buflen, const gcry_mpi_t x) {
	unsigned len;
	size_t nwritten;

	assert(gcry_mpi_cmp_ui(x, 0) >= 0);
	len = (gcry_mpi_get_nbits(x) + 7) / 8;
	assert(len <= buflen);
	memzero(buf, buflen);
	gcry_mpi_print(GCRYMPI_FMT_USG, buf + (buflen - len), len, &nwritten, x);
	assert(nwritten == len);
	}

	static gcry_mpi_t mpi_import(const void *buf, size_t buflen) {
	gcry_mpi_t h;
	_unused_ unsigned len;

	assert_se(gcry_mpi_scan(&h, GCRYMPI_FMT_USG, buf, buflen, NULL) == 0);
	len = (gcry_mpi_get_nbits(h) + 7) / 8;
	assert(len <= buflen);
	assert(gcry_mpi_cmp_ui(h, 0) >= 0);

	return h;
	}

	static void uint64_export(void *buf, size_t buflen, uint64_t x) {
	assert(buflen == 8);
	((uint8_t*) buf)[0] = (x >> 56) & 0xff;
	((uint8_t*) buf)[1] = (x >> 48) & 0xff;
	((uint8_t*) buf)[2] = (x >> 40) & 0xff;
	((uint8_t*) buf)[3] = (x >> 32) & 0xff;
	((uint8_t*) buf)[4] = (x >> 24) & 0xff;
	((uint8_t*) buf)[5] = (x >> 16) & 0xff;
	((uint8_t*) buf)[6] = (x >> 8) & 0xff;
	((uint8_t*) buf)[7] = (x >> 0) & 0xff;
	}

	_pure_ static uint64_t uint64_import(const void *buf, size_t buflen) {
	assert(buflen == 8);
	return
	(uint64_t)(((uint8_t*) buf)[0]) << 56 \|
	(uint64_t)(((uint8_t*) buf)[1]) << 48 \|
	(uint64_t)(((uint8_t*) buf)[2]) << 40 \|
	(uint64_t)(((uint8_t*) buf)[3]) << 32 \|
	(uint64_t)(((uint8_t*) buf)[4]) << 24 \|
	(uint64_t)(((uint8_t*) buf)[5]) << 16 \|
	(uint64_t)(((uint8_t*) buf)[6]) << 8 \|
	(uint64_t)(((uint8_t*) buf)[7]) << 0;
	}

	/* deterministically generate from seed/idx a string of buflen pseudorandom bytes */
	static void det_randomize(void buf, size_t buflen, const void seed, size_t seedlen, uint32_t idx) {
	gcry_md_hd_t hd, hd2;
	size_t olen, cpylen;
	gcry_error_t err;
	uint32_t ctr;

	olen = gcry_md_get_algo_dlen(RND_HASH);
	err = gcry_md_open(&hd, RND_HASH, 0);
	assert_se(gcry_err_code(err) == GPG_ERR_NO_ERROR); /* This shouldn't happen */
	gcry_md_write(hd, seed, seedlen);
	gcry_md_putc(hd, (idx >> 24) & 0xff);
	gcry_md_putc(hd, (idx >> 16) & 0xff);
	gcry_md_putc(hd, (idx >> 8) & 0xff);
	gcry_md_putc(hd, (idx >> 0) & 0xff);

	for (ctr = 0; buflen; ctr++) {
	err = gcry_md_copy(&hd2, hd);
	assert_se(gcry_err_code(err) == GPG_ERR_NO_ERROR); /* This shouldn't happen */
	gcry_md_putc(hd2, (ctr >> 24) & 0xff);
	gcry_md_putc(hd2, (ctr >> 16) & 0xff);
	gcry_md_putc(hd2, (ctr >> 8) & 0xff);
	gcry_md_putc(hd2, (ctr >> 0) & 0xff);
	gcry_md_final(hd2);
	cpylen = (buflen < olen) ? buflen : olen;
	memcpy(buf, gcry_md_read(hd2, RND_HASH), cpylen);
	gcry_md_close(hd2);
	buf += cpylen;
	buflen -= cpylen;
	}
	gcry_md_close(hd);
	}

	/* deterministically generate from seed/idx a prime of length `bits' that is 3 (mod 4) */
	static gcry_mpi_t genprime3mod4(int bits, const void *seed, size_t seedlen, uint32_t idx) {
	size_t buflen = bits / 8;
	uint8_t buf[buflen];
	gcry_mpi_t p;

	assert(bits % 8 == 0);
	assert(buflen > 0);

	det_randomize(buf, buflen, seed, seedlen, idx);
	buf[0] \|= 0xc0; /* set upper two bits, so that n=pq has maximum size */
	buf[buflen - 1] \|= 0x03; /* set lower two bits, to have result 3 (mod 4) */

	p = mpi_import(buf, buflen);
	while (gcry_prime_check(p, 0))
	gcry_mpi_add_ui(p, p, 4);

	return p;
	}

	/* deterministically generate from seed/idx a quadratic residue (mod n) */
	static gcry_mpi_t gensquare(const gcry_mpi_t n, const void *seed, size_t seedlen, uint32_t idx, unsigned secpar) {
	size_t buflen = secpar / 8;
	uint8_t buf[buflen];
	gcry_mpi_t x;

	det_randomize(buf, buflen, seed, seedlen, idx);
	buf[0] &= 0x7f; /* clear upper bit, so that we have x < n */
	x = mpi_import(buf, buflen);
	assert(gcry_mpi_cmp(x, n) < 0);
	gcry_mpi_mulm(x, x, x, n);
	return x;
	}

	/* compute 2^m (mod phi(p)), for a prime p */
	static gcry_mpi_t twopowmodphi(uint64_t m, const gcry_mpi_t p) {
	gcry_mpi_t phi, r;
	int n;

	phi = gcry_mpi_new(0);
	gcry_mpi_sub_ui(phi, p, 1);

	/* count number of used bits in m */
	for (n = 0; (1ULL << n) <= m; n++)
	;

	r = gcry_mpi_new(0);
	gcry_mpi_set_ui(r, 1);
	while (n) { /* square and multiply algorithm for fast exponentiation */
	n--;
	gcry_mpi_mulm(r, r, r, phi);
	if (m & ((uint64_t)1 << n)) {
	gcry_mpi_add(r, r, r);
	if (gcry_mpi_cmp(r, phi) >= 0)
	gcry_mpi_sub(r, r, phi);
	}
	}

	gcry_mpi_release(phi);
	return r;
	}

	/* Decompose $x \in Z_n$ into $(xp,xq) \in Z_p \times Z_q$ using Chinese Remainder Theorem */
	static void CRT_decompose(gcry_mpi_t xp, gcry_mpi_t xq, const gcry_mpi_t x, const gcry_mpi_t p, const gcry_mpi_t q) {
	*xp = gcry_mpi_new(0);
	*xq = gcry_mpi_new(0);
	gcry_mpi_mod(*xp, x, p);
	gcry_mpi_mod(*xq, x, q);
	}

	/* Compose $(xp,xq) \in Z_p \times Z_q$ into $x \in Z_n$ using Chinese Remainder Theorem */
	static void CRT_compose(gcry_mpi_t *x, const gcry_mpi_t xp, const gcry_mpi_t xq, const gcry_mpi_t p, const gcry_mpi_t q) {
	gcry_mpi_t a, u;

	a = gcry_mpi_new(0);
	u = gcry_mpi_new(0);
	*x = gcry_mpi_new(0);
	gcry_mpi_subm(a, xq, xp, q);
	gcry_mpi_invm(u, p, q);
	gcry_mpi_mulm(a, a, u, q); /* a = (xq - xp) / p (mod q) */
	gcry_mpi_mul(*x, p, a);
	gcry_mpi_add(x, x, xp); /* x = p * ((xq - xp) / p mod q) + xp */
	gcry_mpi_release(a);
	gcry_mpi_release(u);
	}

	/******************************************************************************/

	size_t FSPRG_mskinbytes(unsigned _secpar) {
	VALIDATE_SECPAR(_secpar);
	return 2 + 2 * (_secpar / 2) / 8; /* to store header,p,q */
	}

	size_t FSPRG_mpkinbytes(unsigned _secpar) {
	VALIDATE_SECPAR(_secpar);
	return 2 + _secpar / 8; /* to store header,n */
	}

	size_t FSPRG_stateinbytes(unsigned _secpar) {
	VALIDATE_SECPAR(_secpar);
	return 2 + 2 * _secpar / 8 + 8; /* to store header,n,x,epoch */
	}

	static void store_secpar(void *buf, uint16_t secpar) {
	secpar = secpar / 16 - 1;
	((uint8_t*) buf)[0] = (secpar >> 8) & 0xff;
	((uint8_t*) buf)[1] = (secpar >> 0) & 0xff;
	}

	static uint16_t read_secpar(const void *buf) {
	uint16_t secpar;
	secpar =
	(uint16_t)(((uint8_t*) buf)[0]) << 8 \|
	(uint16_t)(((uint8_t*) buf)[1]) << 0;
	return 16 * (secpar + 1);
	}

	void FSPRG_GenMK(void msk, void mpk, const void *seed, size_t seedlen, unsigned _secpar) {
	uint8_t iseed[FSPRG_RECOMMENDED_SEEDLEN];
	gcry_mpi_t n, p, q;
	uint16_t secpar;

	VALIDATE_SECPAR(_secpar);
	secpar = _secpar;

	initialize_libgcrypt(false);

	if (!seed) {
	gcry_randomize(iseed, FSPRG_RECOMMENDED_SEEDLEN, GCRY_STRONG_RANDOM);
	seed = iseed;
	seedlen = FSPRG_RECOMMENDED_SEEDLEN;
	}

	p = genprime3mod4(secpar / 2, seed, seedlen, RND_GEN_P);
	q = genprime3mod4(secpar / 2, seed, seedlen, RND_GEN_Q);

	if (msk) {
	store_secpar(msk + 0, secpar);
	mpi_export(msk + 2 + 0 * (secpar / 2) / 8, (secpar / 2) / 8, p);
	mpi_export(msk + 2 + 1 * (secpar / 2) / 8, (secpar / 2) / 8, q);
	}

	if (mpk) {
	n = gcry_mpi_new(0);
	gcry_mpi_mul(n, p, q);
	assert(gcry_mpi_get_nbits(n) == secpar);

	store_secpar(mpk + 0, secpar);
	mpi_export(mpk + 2, secpar / 8, n);

	gcry_mpi_release(n);
	}

	gcry_mpi_release(p);
	gcry_mpi_release(q);
	}

	void FSPRG_GenState0(void state, const void mpk, const void *seed, size_t seedlen) {
	gcry_mpi_t n, x;
	uint16_t secpar;

	initialize_libgcrypt(false);

	secpar = read_secpar(mpk + 0);
	n = mpi_import(mpk + 2, secpar / 8);
	x = gensquare(n, seed, seedlen, RND_GEN_X, secpar);

	memcpy(state, mpk, 2 + secpar / 8);
	mpi_export(state + 2 + 1 * secpar / 8, secpar / 8, x);
	memzero(state + 2 + 2 * secpar / 8, 8);

	gcry_mpi_release(n);
	gcry_mpi_release(x);
	}

	void FSPRG_Evolve(void *state) {
	gcry_mpi_t n, x;
	uint16_t secpar;
	uint64_t epoch;

	initialize_libgcrypt(false);

	secpar = read_secpar(state + 0);
	n = mpi_import(state + 2 + 0 * secpar / 8, secpar / 8);
	x = mpi_import(state + 2 + 1 * secpar / 8, secpar / 8);
	epoch = uint64_import(state + 2 + 2 * secpar / 8, 8);

	gcry_mpi_mulm(x, x, x, n);
	epoch++;

	mpi_export(state + 2 + 1 * secpar / 8, secpar / 8, x);
	uint64_export(state + 2 + 2 * secpar / 8, 8, epoch);

	gcry_mpi_release(n);
	gcry_mpi_release(x);
	}

	uint64_t FSPRG_GetEpoch(const void *state) {
	uint16_t secpar;
	secpar = read_secpar(state + 0);
	return uint64_import(state + 2 + 2 * secpar / 8, 8);
	}

	void FSPRG_Seek(void state, uint64_t epoch, const void msk, const void *seed, size_t seedlen) {
	gcry_mpi_t p, q, n, x, xp, xq, kp, kq, xm;
	uint16_t secpar;

	initialize_libgcrypt(false);

	secpar = read_secpar(msk + 0);
	p = mpi_import(msk + 2 + 0 * (secpar / 2) / 8, (secpar / 2) / 8);
	q = mpi_import(msk + 2 + 1 * (secpar / 2) / 8, (secpar / 2) / 8);

	n = gcry_mpi_new(0);
	gcry_mpi_mul(n, p, q);

	x = gensquare(n, seed, seedlen, RND_GEN_X, secpar);
	CRT_decompose(&xp, &xq, x, p, q); /* split (mod n) into (mod p) and (mod q) using CRT */

	kp = twopowmodphi(epoch, p); /* compute 2^epoch (mod phi(p)) */
	kq = twopowmodphi(epoch, q); /* compute 2^epoch (mod phi(q)) */

	gcry_mpi_powm(xp, xp, kp, p); /* compute x^(2^epoch) (mod p) */
	gcry_mpi_powm(xq, xq, kq, q); /* compute x^(2^epoch) (mod q) */

	CRT_compose(&xm, xp, xq, p, q); /* combine (mod p) and (mod q) to (mod n) using CRT */

	store_secpar(state + 0, secpar);
	mpi_export(state + 2 + 0 * secpar / 8, secpar / 8, n);
	mpi_export(state + 2 + 1 * secpar / 8, secpar / 8, xm);
	uint64_export(state + 2 + 2 * secpar / 8, 8, epoch);

	gcry_mpi_release(p);
	gcry_mpi_release(q);
	gcry_mpi_release(n);
	gcry_mpi_release(x);
	gcry_mpi_release(xp);
	gcry_mpi_release(xq);
	gcry_mpi_release(kp);
	gcry_mpi_release(kq);
	gcry_mpi_release(xm);
	}

	void FSPRG_GetKey(const void state, void key, size_t keylen, uint32_t idx) {
	uint16_t secpar;

	initialize_libgcrypt(false);

	secpar = read_secpar(state + 0);
	det_randomize(key, keylen, state + 2, 2 * secpar / 8 + 8, idx);
	}