openssh/sntrup761.c
djm@openbsd.org 0ca128c9ee
upstream: use 64 bit math to avoid signed underflow. upstream code
relies on using -fwrapv to provide defined over/underflow behaviour, but we
use -ftrapv to catch integer errors and abort the program. ok dtucker@

OpenBSD-Commit-ID: 8933369b33c17b5f02479503d0a92d87bc3a574b
2024-09-16 15:37:51 +10:00

2160 lines
78 KiB
C

/* $OpenBSD: sntrup761.c,v 1.8 2024/09/16 05:37:05 djm Exp $ */
/*
* Public Domain, Authors:
* - Daniel J. Bernstein
* - Chitchanok Chuengsatiansup
* - Tanja Lange
* - Christine van Vredendaal
*/
#include "includes.h"
#ifdef USE_SNTRUP761X25519
#include <string.h>
#include "crypto_api.h"
#define crypto_declassify(x, y) do {} while (0)
#define int8 crypto_int8
#define uint8 crypto_uint8
#define int16 crypto_int16
#define uint16 crypto_uint16
#define int32 crypto_int32
#define uint32 crypto_uint32
#define int64 crypto_int64
#define uint64 crypto_uint64
extern volatile crypto_int16 crypto_int16_optblocker;
extern volatile crypto_int32 crypto_int32_optblocker;
extern volatile crypto_int64 crypto_int64_optblocker;
/* from supercop-20240808/cryptoint/crypto_int16.h */
/* auto-generated: cd cryptoint; ./autogen */
/* cryptoint 20240806 */
#ifndef crypto_int16_h
#define crypto_int16_h
#define crypto_int16 int16_t
#define crypto_int16_unsigned uint16_t
__attribute__((unused))
static inline
crypto_int16 crypto_int16_load(const unsigned char *crypto_int16_s) {
crypto_int16 crypto_int16_z = 0;
crypto_int16_z |= ((crypto_int16) (*crypto_int16_s++)) << 0;
crypto_int16_z |= ((crypto_int16) (*crypto_int16_s++)) << 8;
return crypto_int16_z;
}
__attribute__((unused))
static inline
void crypto_int16_store(unsigned char *crypto_int16_s,crypto_int16 crypto_int16_x) {
*crypto_int16_s++ = crypto_int16_x >> 0;
*crypto_int16_s++ = crypto_int16_x >> 8;
}
__attribute__((unused))
static inline
crypto_int16 crypto_int16_negative_mask(crypto_int16 crypto_int16_x) {
#if defined(__GNUC__) && defined(__x86_64__)
__asm__ ("sarw $15,%0" : "+r"(crypto_int16_x) : : "cc");
return crypto_int16_x;
#elif defined(__GNUC__) && defined(__aarch64__)
crypto_int16 crypto_int16_y;
__asm__ ("sbfx %w0,%w1,15,1" : "=r"(crypto_int16_y) : "r"(crypto_int16_x) : );
return crypto_int16_y;
#else
crypto_int16_x >>= 16-6;
crypto_int16_x ^= crypto_int16_optblocker;
crypto_int16_x >>= 5;
return crypto_int16_x;
#endif
}
__attribute__((unused))
static inline
crypto_int16_unsigned crypto_int16_unsigned_topbit_01(crypto_int16_unsigned crypto_int16_x) {
#if defined(__GNUC__) && defined(__x86_64__)
__asm__ ("shrw $15,%0" : "+r"(crypto_int16_x) : : "cc");
return crypto_int16_x;
#elif defined(__GNUC__) && defined(__aarch64__)
crypto_int16 crypto_int16_y;
__asm__ ("ubfx %w0,%w1,15,1" : "=r"(crypto_int16_y) : "r"(crypto_int16_x) : );
return crypto_int16_y;
#else
crypto_int16_x >>= 16-6;
crypto_int16_x ^= crypto_int16_optblocker;
crypto_int16_x >>= 5;
return crypto_int16_x;
#endif
}
__attribute__((unused))
static inline
crypto_int16 crypto_int16_negative_01(crypto_int16 crypto_int16_x) {
return crypto_int16_unsigned_topbit_01(crypto_int16_x);
}
__attribute__((unused))
static inline
crypto_int16 crypto_int16_topbit_mask(crypto_int16 crypto_int16_x) {
return crypto_int16_negative_mask(crypto_int16_x);
}
__attribute__((unused))
static inline
crypto_int16 crypto_int16_topbit_01(crypto_int16 crypto_int16_x) {
return crypto_int16_unsigned_topbit_01(crypto_int16_x);
}
__attribute__((unused))
static inline
crypto_int16 crypto_int16_bottombit_mask(crypto_int16 crypto_int16_x) {
#if defined(__GNUC__) && defined(__x86_64__)
__asm__ ("andw $1,%0" : "+r"(crypto_int16_x) : : "cc");
return -crypto_int16_x;
#elif defined(__GNUC__) && defined(__aarch64__)
crypto_int16 crypto_int16_y;
__asm__ ("sbfx %w0,%w1,0,1" : "=r"(crypto_int16_y) : "r"(crypto_int16_x) : );
return crypto_int16_y;
#else
crypto_int16_x &= 1 ^ crypto_int16_optblocker;
return -crypto_int16_x;
#endif
}
__attribute__((unused))
static inline
crypto_int16 crypto_int16_bottombit_01(crypto_int16 crypto_int16_x) {
#if defined(__GNUC__) && defined(__x86_64__)
__asm__ ("andw $1,%0" : "+r"(crypto_int16_x) : : "cc");
return crypto_int16_x;
#elif defined(__GNUC__) && defined(__aarch64__)
crypto_int16 crypto_int16_y;
__asm__ ("ubfx %w0,%w1,0,1" : "=r"(crypto_int16_y) : "r"(crypto_int16_x) : );
return crypto_int16_y;
#else
crypto_int16_x &= 1 ^ crypto_int16_optblocker;
return crypto_int16_x;
#endif
}
__attribute__((unused))
static inline
crypto_int16 crypto_int16_bitinrangepublicpos_mask(crypto_int16 crypto_int16_x,crypto_int16 crypto_int16_s) {
#if defined(__GNUC__) && defined(__x86_64__)
__asm__ ("sarw %%cl,%0" : "+r"(crypto_int16_x) : "c"(crypto_int16_s) : "cc");
#elif defined(__GNUC__) && defined(__aarch64__)
__asm__ ("sxth %w0,%w0\n asr %w0,%w0,%w1" : "+&r"(crypto_int16_x) : "r"(crypto_int16_s) : );
#else
crypto_int16_x >>= crypto_int16_s ^ crypto_int16_optblocker;
#endif
return crypto_int16_bottombit_mask(crypto_int16_x);
}
__attribute__((unused))
static inline
crypto_int16 crypto_int16_bitinrangepublicpos_01(crypto_int16 crypto_int16_x,crypto_int16 crypto_int16_s) {
#if defined(__GNUC__) && defined(__x86_64__)
__asm__ ("sarw %%cl,%0" : "+r"(crypto_int16_x) : "c"(crypto_int16_s) : "cc");
#elif defined(__GNUC__) && defined(__aarch64__)
__asm__ ("sxth %w0,%w0\n asr %w0,%w0,%w1" : "+&r"(crypto_int16_x) : "r"(crypto_int16_s) : );
#else
crypto_int16_x >>= crypto_int16_s ^ crypto_int16_optblocker;
#endif
return crypto_int16_bottombit_01(crypto_int16_x);
}
__attribute__((unused))
static inline
crypto_int16 crypto_int16_shlmod(crypto_int16 crypto_int16_x,crypto_int16 crypto_int16_s) {
#if defined(__GNUC__) && defined(__x86_64__)
crypto_int16_s &= 15;
__asm__ ("shlw %%cl,%0" : "+r"(crypto_int16_x) : "c"(crypto_int16_s) : "cc");
#elif defined(__GNUC__) && defined(__aarch64__)
__asm__ ("and %w0,%w0,15\n and %w1,%w1,65535\n lsl %w1,%w1,%w0" : "+&r"(crypto_int16_s), "+r"(crypto_int16_x) : : );
#else
int crypto_int16_k, crypto_int16_l;
for (crypto_int16_l = 0,crypto_int16_k = 1;crypto_int16_k < 16;++crypto_int16_l,crypto_int16_k *= 2)
crypto_int16_x ^= (crypto_int16_x ^ (crypto_int16_x << crypto_int16_k)) & crypto_int16_bitinrangepublicpos_mask(crypto_int16_s,crypto_int16_l);
#endif
return crypto_int16_x;
}
__attribute__((unused))
static inline
crypto_int16 crypto_int16_shrmod(crypto_int16 crypto_int16_x,crypto_int16 crypto_int16_s) {
#if defined(__GNUC__) && defined(__x86_64__)
crypto_int16_s &= 15;
__asm__ ("sarw %%cl,%0" : "+r"(crypto_int16_x) : "c"(crypto_int16_s) : "cc");
#elif defined(__GNUC__) && defined(__aarch64__)
__asm__ ("and %w0,%w0,15\n sxth %w1,%w1\n asr %w1,%w1,%w0" : "+&r"(crypto_int16_s), "+r"(crypto_int16_x) : : );
#else
int crypto_int16_k, crypto_int16_l;
for (crypto_int16_l = 0,crypto_int16_k = 1;crypto_int16_k < 16;++crypto_int16_l,crypto_int16_k *= 2)
crypto_int16_x ^= (crypto_int16_x ^ (crypto_int16_x >> crypto_int16_k)) & crypto_int16_bitinrangepublicpos_mask(crypto_int16_s,crypto_int16_l);
#endif
return crypto_int16_x;
}
__attribute__((unused))
static inline
crypto_int16 crypto_int16_bitmod_mask(crypto_int16 crypto_int16_x,crypto_int16 crypto_int16_s) {
crypto_int16_x = crypto_int16_shrmod(crypto_int16_x,crypto_int16_s);
return crypto_int16_bottombit_mask(crypto_int16_x);
}
__attribute__((unused))
static inline
crypto_int16 crypto_int16_bitmod_01(crypto_int16 crypto_int16_x,crypto_int16 crypto_int16_s) {
crypto_int16_x = crypto_int16_shrmod(crypto_int16_x,crypto_int16_s);
return crypto_int16_bottombit_01(crypto_int16_x);
}
__attribute__((unused))
static inline
crypto_int16 crypto_int16_nonzero_mask(crypto_int16 crypto_int16_x) {
#if defined(__GNUC__) && defined(__x86_64__)
crypto_int16 crypto_int16_q,crypto_int16_z;
__asm__ ("xorw %0,%0\n movw $-1,%1\n testw %2,%2\n cmovnew %1,%0" : "=&r"(crypto_int16_z), "=&r"(crypto_int16_q) : "r"(crypto_int16_x) : "cc");
return crypto_int16_z;
#elif defined(__GNUC__) && defined(__aarch64__)
crypto_int16 crypto_int16_z;
__asm__ ("tst %w1,65535\n csetm %w0,ne" : "=r"(crypto_int16_z) : "r"(crypto_int16_x) : "cc");
return crypto_int16_z;
#else
crypto_int16_x |= -crypto_int16_x;
return crypto_int16_negative_mask(crypto_int16_x);
#endif
}
__attribute__((unused))
static inline
crypto_int16 crypto_int16_nonzero_01(crypto_int16 crypto_int16_x) {
#if defined(__GNUC__) && defined(__x86_64__)
crypto_int16 crypto_int16_q,crypto_int16_z;
__asm__ ("xorw %0,%0\n movw $1,%1\n testw %2,%2\n cmovnew %1,%0" : "=&r"(crypto_int16_z), "=&r"(crypto_int16_q) : "r"(crypto_int16_x) : "cc");
return crypto_int16_z;
#elif defined(__GNUC__) && defined(__aarch64__)
crypto_int16 crypto_int16_z;
__asm__ ("tst %w1,65535\n cset %w0,ne" : "=r"(crypto_int16_z) : "r"(crypto_int16_x) : "cc");
return crypto_int16_z;
#else
crypto_int16_x |= -crypto_int16_x;
return crypto_int16_unsigned_topbit_01(crypto_int16_x);
#endif
}
__attribute__((unused))
static inline
crypto_int16 crypto_int16_positive_mask(crypto_int16 crypto_int16_x) {
#if defined(__GNUC__) && defined(__x86_64__)
crypto_int16 crypto_int16_q,crypto_int16_z;
__asm__ ("xorw %0,%0\n movw $-1,%1\n testw %2,%2\n cmovgw %1,%0" : "=&r"(crypto_int16_z), "=&r"(crypto_int16_q) : "r"(crypto_int16_x) : "cc");
return crypto_int16_z;
#elif defined(__GNUC__) && defined(__aarch64__)
crypto_int16 crypto_int16_z;
__asm__ ("sxth %w0,%w1\n cmp %w0,0\n csetm %w0,gt" : "=r"(crypto_int16_z) : "r"(crypto_int16_x) : "cc");
return crypto_int16_z;
#else
crypto_int16 crypto_int16_z = -crypto_int16_x;
crypto_int16_z ^= crypto_int16_x & crypto_int16_z;
return crypto_int16_negative_mask(crypto_int16_z);
#endif
}
__attribute__((unused))
static inline
crypto_int16 crypto_int16_positive_01(crypto_int16 crypto_int16_x) {
#if defined(__GNUC__) && defined(__x86_64__)
crypto_int16 crypto_int16_q,crypto_int16_z;
__asm__ ("xorw %0,%0\n movw $1,%1\n testw %2,%2\n cmovgw %1,%0" : "=&r"(crypto_int16_z), "=&r"(crypto_int16_q) : "r"(crypto_int16_x) : "cc");
return crypto_int16_z;
#elif defined(__GNUC__) && defined(__aarch64__)
crypto_int16 crypto_int16_z;
__asm__ ("sxth %w0,%w1\n cmp %w0,0\n cset %w0,gt" : "=r"(crypto_int16_z) : "r"(crypto_int16_x) : "cc");
return crypto_int16_z;
#else
crypto_int16 crypto_int16_z = -crypto_int16_x;
crypto_int16_z ^= crypto_int16_x & crypto_int16_z;
return crypto_int16_unsigned_topbit_01(crypto_int16_z);
#endif
}
__attribute__((unused))
static inline
crypto_int16 crypto_int16_zero_mask(crypto_int16 crypto_int16_x) {
#if defined(__GNUC__) && defined(__x86_64__)
crypto_int16 crypto_int16_q,crypto_int16_z;
__asm__ ("xorw %0,%0\n movw $-1,%1\n testw %2,%2\n cmovew %1,%0" : "=&r"(crypto_int16_z), "=&r"(crypto_int16_q) : "r"(crypto_int16_x) : "cc");
return crypto_int16_z;
#elif defined(__GNUC__) && defined(__aarch64__)
crypto_int16 crypto_int16_z;
__asm__ ("tst %w1,65535\n csetm %w0,eq" : "=r"(crypto_int16_z) : "r"(crypto_int16_x) : "cc");
return crypto_int16_z;
#else
return ~crypto_int16_nonzero_mask(crypto_int16_x);
#endif
}
__attribute__((unused))
static inline
crypto_int16 crypto_int16_zero_01(crypto_int16 crypto_int16_x) {
#if defined(__GNUC__) && defined(__x86_64__)
crypto_int16 crypto_int16_q,crypto_int16_z;
__asm__ ("xorw %0,%0\n movw $1,%1\n testw %2,%2\n cmovew %1,%0" : "=&r"(crypto_int16_z), "=&r"(crypto_int16_q) : "r"(crypto_int16_x) : "cc");
return crypto_int16_z;
#elif defined(__GNUC__) && defined(__aarch64__)
crypto_int16 crypto_int16_z;
__asm__ ("tst %w1,65535\n cset %w0,eq" : "=r"(crypto_int16_z) : "r"(crypto_int16_x) : "cc");
return crypto_int16_z;
#else
return 1-crypto_int16_nonzero_01(crypto_int16_x);
#endif
}
__attribute__((unused))
static inline
crypto_int16 crypto_int16_unequal_mask(crypto_int16 crypto_int16_x,crypto_int16 crypto_int16_y) {
#if defined(__GNUC__) && defined(__x86_64__)
crypto_int16 crypto_int16_q,crypto_int16_z;
__asm__ ("xorw %0,%0\n movw $-1,%1\n cmpw %3,%2\n cmovnew %1,%0" : "=&r"(crypto_int16_z), "=&r"(crypto_int16_q) : "r"(crypto_int16_x), "r"(crypto_int16_y) : "cc");
return crypto_int16_z;
#elif defined(__GNUC__) && defined(__aarch64__)
crypto_int16 crypto_int16_z;
__asm__ ("and %w0,%w1,65535\n cmp %w0,%w2,uxth\n csetm %w0,ne" : "=&r"(crypto_int16_z) : "r"(crypto_int16_x), "r"(crypto_int16_y) : "cc");
return crypto_int16_z;
#else
return crypto_int16_nonzero_mask(crypto_int16_x ^ crypto_int16_y);
#endif
}
__attribute__((unused))
static inline
crypto_int16 crypto_int16_unequal_01(crypto_int16 crypto_int16_x,crypto_int16 crypto_int16_y) {
#if defined(__GNUC__) && defined(__x86_64__)
crypto_int16 crypto_int16_q,crypto_int16_z;
__asm__ ("xorw %0,%0\n movw $1,%1\n cmpw %3,%2\n cmovnew %1,%0" : "=&r"(crypto_int16_z), "=&r"(crypto_int16_q) : "r"(crypto_int16_x), "r"(crypto_int16_y) : "cc");
return crypto_int16_z;
#elif defined(__GNUC__) && defined(__aarch64__)
crypto_int16 crypto_int16_z;
__asm__ ("and %w0,%w1,65535\n cmp %w0,%w2,uxth\n cset %w0,ne" : "=&r"(crypto_int16_z) : "r"(crypto_int16_x), "r"(crypto_int16_y) : "cc");
return crypto_int16_z;
#else
return crypto_int16_nonzero_01(crypto_int16_x ^ crypto_int16_y);
#endif
}
__attribute__((unused))
static inline
crypto_int16 crypto_int16_equal_mask(crypto_int16 crypto_int16_x,crypto_int16 crypto_int16_y) {
#if defined(__GNUC__) && defined(__x86_64__)
crypto_int16 crypto_int16_q,crypto_int16_z;
__asm__ ("xorw %0,%0\n movw $-1,%1\n cmpw %3,%2\n cmovew %1,%0" : "=&r"(crypto_int16_z), "=&r"(crypto_int16_q) : "r"(crypto_int16_x), "r"(crypto_int16_y) : "cc");
return crypto_int16_z;
#elif defined(__GNUC__) && defined(__aarch64__)
crypto_int16 crypto_int16_z;
__asm__ ("and %w0,%w1,65535\n cmp %w0,%w2,uxth\n csetm %w0,eq" : "=&r"(crypto_int16_z) : "r"(crypto_int16_x), "r"(crypto_int16_y) : "cc");
return crypto_int16_z;
#else
return ~crypto_int16_unequal_mask(crypto_int16_x,crypto_int16_y);
#endif
}
__attribute__((unused))
static inline
crypto_int16 crypto_int16_equal_01(crypto_int16 crypto_int16_x,crypto_int16 crypto_int16_y) {
#if defined(__GNUC__) && defined(__x86_64__)
crypto_int16 crypto_int16_q,crypto_int16_z;
__asm__ ("xorw %0,%0\n movw $1,%1\n cmpw %3,%2\n cmovew %1,%0" : "=&r"(crypto_int16_z), "=&r"(crypto_int16_q) : "r"(crypto_int16_x), "r"(crypto_int16_y) : "cc");
return crypto_int16_z;
#elif defined(__GNUC__) && defined(__aarch64__)
crypto_int16 crypto_int16_z;
__asm__ ("and %w0,%w1,65535\n cmp %w0,%w2,uxth\n cset %w0,eq" : "=&r"(crypto_int16_z) : "r"(crypto_int16_x), "r"(crypto_int16_y) : "cc");
return crypto_int16_z;
#else
return 1-crypto_int16_unequal_01(crypto_int16_x,crypto_int16_y);
#endif
}
__attribute__((unused))
static inline
crypto_int16 crypto_int16_min(crypto_int16 crypto_int16_x,crypto_int16 crypto_int16_y) {
#if defined(__GNUC__) && defined(__x86_64__)
__asm__ ("cmpw %1,%0\n cmovgw %1,%0" : "+r"(crypto_int16_x) : "r"(crypto_int16_y) : "cc");
return crypto_int16_x;
#elif defined(__GNUC__) && defined(__aarch64__)
__asm__ ("sxth %w0,%w0\n cmp %w0,%w1,sxth\n csel %w0,%w0,%w1,lt" : "+&r"(crypto_int16_x) : "r"(crypto_int16_y) : "cc");
return crypto_int16_x;
#else
crypto_int16 crypto_int16_r = crypto_int16_y ^ crypto_int16_x;
crypto_int16 crypto_int16_z = crypto_int16_y - crypto_int16_x;
crypto_int16_z ^= crypto_int16_r & (crypto_int16_z ^ crypto_int16_y);
crypto_int16_z = crypto_int16_negative_mask(crypto_int16_z);
crypto_int16_z &= crypto_int16_r;
return crypto_int16_x ^ crypto_int16_z;
#endif
}
__attribute__((unused))
static inline
crypto_int16 crypto_int16_max(crypto_int16 crypto_int16_x,crypto_int16 crypto_int16_y) {
#if defined(__GNUC__) && defined(__x86_64__)
__asm__ ("cmpw %1,%0\n cmovlw %1,%0" : "+r"(crypto_int16_x) : "r"(crypto_int16_y) : "cc");
return crypto_int16_x;
#elif defined(__GNUC__) && defined(__aarch64__)
__asm__ ("sxth %w0,%w0\n cmp %w0,%w1,sxth\n csel %w0,%w1,%w0,lt" : "+&r"(crypto_int16_x) : "r"(crypto_int16_y) : "cc");
return crypto_int16_x;
#else
crypto_int16 crypto_int16_r = crypto_int16_y ^ crypto_int16_x;
crypto_int16 crypto_int16_z = crypto_int16_y - crypto_int16_x;
crypto_int16_z ^= crypto_int16_r & (crypto_int16_z ^ crypto_int16_y);
crypto_int16_z = crypto_int16_negative_mask(crypto_int16_z);
crypto_int16_z &= crypto_int16_r;
return crypto_int16_y ^ crypto_int16_z;
#endif
}
__attribute__((unused))
static inline
void crypto_int16_minmax(crypto_int16 *crypto_int16_p,crypto_int16 *crypto_int16_q) {
crypto_int16 crypto_int16_x = *crypto_int16_p;
crypto_int16 crypto_int16_y = *crypto_int16_q;
#if defined(__GNUC__) && defined(__x86_64__)
crypto_int16 crypto_int16_z;
__asm__ ("cmpw %2,%1\n movw %1,%0\n cmovgw %2,%1\n cmovgw %0,%2" : "=&r"(crypto_int16_z), "+&r"(crypto_int16_x), "+r"(crypto_int16_y) : : "cc");
*crypto_int16_p = crypto_int16_x;
*crypto_int16_q = crypto_int16_y;
#elif defined(__GNUC__) && defined(__aarch64__)
crypto_int16 crypto_int16_r, crypto_int16_s;
__asm__ ("sxth %w0,%w0\n cmp %w0,%w3,sxth\n csel %w1,%w0,%w3,lt\n csel %w2,%w3,%w0,lt" : "+&r"(crypto_int16_x), "=&r"(crypto_int16_r), "=r"(crypto_int16_s) : "r"(crypto_int16_y) : "cc");
*crypto_int16_p = crypto_int16_r;
*crypto_int16_q = crypto_int16_s;
#else
crypto_int16 crypto_int16_r = crypto_int16_y ^ crypto_int16_x;
crypto_int16 crypto_int16_z = crypto_int16_y - crypto_int16_x;
crypto_int16_z ^= crypto_int16_r & (crypto_int16_z ^ crypto_int16_y);
crypto_int16_z = crypto_int16_negative_mask(crypto_int16_z);
crypto_int16_z &= crypto_int16_r;
crypto_int16_x ^= crypto_int16_z;
crypto_int16_y ^= crypto_int16_z;
*crypto_int16_p = crypto_int16_x;
*crypto_int16_q = crypto_int16_y;
#endif
}
__attribute__((unused))
static inline
crypto_int16 crypto_int16_smaller_mask(crypto_int16 crypto_int16_x,crypto_int16 crypto_int16_y) {
#if defined(__GNUC__) && defined(__x86_64__)
crypto_int16 crypto_int16_q,crypto_int16_z;
__asm__ ("xorw %0,%0\n movw $-1,%1\n cmpw %3,%2\n cmovlw %1,%0" : "=&r"(crypto_int16_z), "=&r"(crypto_int16_q) : "r"(crypto_int16_x), "r"(crypto_int16_y) : "cc");
return crypto_int16_z;
#elif defined(__GNUC__) && defined(__aarch64__)
crypto_int16 crypto_int16_z;
__asm__ ("sxth %w0,%w1\n cmp %w0,%w2,sxth\n csetm %w0,lt" : "=&r"(crypto_int16_z) : "r"(crypto_int16_x), "r"(crypto_int16_y) : "cc");
return crypto_int16_z;
#else
crypto_int16 crypto_int16_r = crypto_int16_x ^ crypto_int16_y;
crypto_int16 crypto_int16_z = crypto_int16_x - crypto_int16_y;
crypto_int16_z ^= crypto_int16_r & (crypto_int16_z ^ crypto_int16_x);
return crypto_int16_negative_mask(crypto_int16_z);
#endif
}
__attribute__((unused))
static inline
crypto_int16 crypto_int16_smaller_01(crypto_int16 crypto_int16_x,crypto_int16 crypto_int16_y) {
#if defined(__GNUC__) && defined(__x86_64__)
crypto_int16 crypto_int16_q,crypto_int16_z;
__asm__ ("xorw %0,%0\n movw $1,%1\n cmpw %3,%2\n cmovlw %1,%0" : "=&r"(crypto_int16_z), "=&r"(crypto_int16_q) : "r"(crypto_int16_x), "r"(crypto_int16_y) : "cc");
return crypto_int16_z;
#elif defined(__GNUC__) && defined(__aarch64__)
crypto_int16 crypto_int16_z;
__asm__ ("sxth %w0,%w1\n cmp %w0,%w2,sxth\n cset %w0,lt" : "=&r"(crypto_int16_z) : "r"(crypto_int16_x), "r"(crypto_int16_y) : "cc");
return crypto_int16_z;
#else
crypto_int16 crypto_int16_r = crypto_int16_x ^ crypto_int16_y;
crypto_int16 crypto_int16_z = crypto_int16_x - crypto_int16_y;
crypto_int16_z ^= crypto_int16_r & (crypto_int16_z ^ crypto_int16_x);
return crypto_int16_unsigned_topbit_01(crypto_int16_z);
#endif
}
__attribute__((unused))
static inline
crypto_int16 crypto_int16_leq_mask(crypto_int16 crypto_int16_x,crypto_int16 crypto_int16_y) {
#if defined(__GNUC__) && defined(__x86_64__)
crypto_int16 crypto_int16_q,crypto_int16_z;
__asm__ ("xorw %0,%0\n movw $-1,%1\n cmpw %3,%2\n cmovlew %1,%0" : "=&r"(crypto_int16_z), "=&r"(crypto_int16_q) : "r"(crypto_int16_x), "r"(crypto_int16_y) : "cc");
return crypto_int16_z;
#elif defined(__GNUC__) && defined(__aarch64__)
crypto_int16 crypto_int16_z;
__asm__ ("sxth %w0,%w1\n cmp %w0,%w2,sxth\n csetm %w0,le" : "=&r"(crypto_int16_z) : "r"(crypto_int16_x), "r"(crypto_int16_y) : "cc");
return crypto_int16_z;
#else
return ~crypto_int16_smaller_mask(crypto_int16_y,crypto_int16_x);
#endif
}
__attribute__((unused))
static inline
crypto_int16 crypto_int16_leq_01(crypto_int16 crypto_int16_x,crypto_int16 crypto_int16_y) {
#if defined(__GNUC__) && defined(__x86_64__)
crypto_int16 crypto_int16_q,crypto_int16_z;
__asm__ ("xorw %0,%0\n movw $1,%1\n cmpw %3,%2\n cmovlew %1,%0" : "=&r"(crypto_int16_z), "=&r"(crypto_int16_q) : "r"(crypto_int16_x), "r"(crypto_int16_y) : "cc");
return crypto_int16_z;
#elif defined(__GNUC__) && defined(__aarch64__)
crypto_int16 crypto_int16_z;
__asm__ ("sxth %w0,%w1\n cmp %w0,%w2,sxth\n cset %w0,le" : "=&r"(crypto_int16_z) : "r"(crypto_int16_x), "r"(crypto_int16_y) : "cc");
return crypto_int16_z;
#else
return 1-crypto_int16_smaller_01(crypto_int16_y,crypto_int16_x);
#endif
}
__attribute__((unused))
static inline
int crypto_int16_ones_num(crypto_int16 crypto_int16_x) {
crypto_int16_unsigned crypto_int16_y = crypto_int16_x;
const crypto_int16 C0 = 0x5555;
const crypto_int16 C1 = 0x3333;
const crypto_int16 C2 = 0x0f0f;
crypto_int16_y -= ((crypto_int16_y >> 1) & C0);
crypto_int16_y = (crypto_int16_y & C1) + ((crypto_int16_y >> 2) & C1);
crypto_int16_y = (crypto_int16_y + (crypto_int16_y >> 4)) & C2;
crypto_int16_y = (crypto_int16_y + (crypto_int16_y >> 8)) & 0xff;
return crypto_int16_y;
}
__attribute__((unused))
static inline
int crypto_int16_bottomzeros_num(crypto_int16 crypto_int16_x) {
#if defined(__GNUC__) && defined(__x86_64__)
crypto_int16 fallback = 16;
__asm__ ("bsfw %0,%0\n cmovew %1,%0" : "+&r"(crypto_int16_x) : "r"(fallback) : "cc");
return crypto_int16_x;
#elif defined(__GNUC__) && defined(__aarch64__)
int64_t crypto_int16_y;
__asm__ ("orr %w0,%w1,-65536\n rbit %w0,%w0\n clz %w0,%w0" : "=r"(crypto_int16_y) : "r"(crypto_int16_x) : );
return crypto_int16_y;
#else
crypto_int16 crypto_int16_y = crypto_int16_x ^ (crypto_int16_x-1);
crypto_int16_y = ((crypto_int16) crypto_int16_y) >> 1;
crypto_int16_y &= ~(crypto_int16_x & (((crypto_int16) 1) << (16-1)));
return crypto_int16_ones_num(crypto_int16_y);
#endif
}
#endif
/* from supercop-20240808/cryptoint/crypto_int32.h */
/* auto-generated: cd cryptoint; ./autogen */
/* cryptoint 20240806 */
#ifndef crypto_int32_h
#define crypto_int32_h
#define crypto_int32 int32_t
#define crypto_int32_unsigned uint32_t
__attribute__((unused))
static inline
crypto_int32 crypto_int32_load(const unsigned char *crypto_int32_s) {
crypto_int32 crypto_int32_z = 0;
crypto_int32_z |= ((crypto_int32) (*crypto_int32_s++)) << 0;
crypto_int32_z |= ((crypto_int32) (*crypto_int32_s++)) << 8;
crypto_int32_z |= ((crypto_int32) (*crypto_int32_s++)) << 16;
crypto_int32_z |= ((crypto_int32) (*crypto_int32_s++)) << 24;
return crypto_int32_z;
}
__attribute__((unused))
static inline
void crypto_int32_store(unsigned char *crypto_int32_s,crypto_int32 crypto_int32_x) {
*crypto_int32_s++ = crypto_int32_x >> 0;
*crypto_int32_s++ = crypto_int32_x >> 8;
*crypto_int32_s++ = crypto_int32_x >> 16;
*crypto_int32_s++ = crypto_int32_x >> 24;
}
__attribute__((unused))
static inline
crypto_int32 crypto_int32_negative_mask(crypto_int32 crypto_int32_x) {
#if defined(__GNUC__) && defined(__x86_64__)
__asm__ ("sarl $31,%0" : "+r"(crypto_int32_x) : : "cc");
return crypto_int32_x;
#elif defined(__GNUC__) && defined(__aarch64__)
crypto_int32 crypto_int32_y;
__asm__ ("asr %w0,%w1,31" : "=r"(crypto_int32_y) : "r"(crypto_int32_x) : );
return crypto_int32_y;
#else
crypto_int32_x >>= 32-6;
crypto_int32_x ^= crypto_int32_optblocker;
crypto_int32_x >>= 5;
return crypto_int32_x;
#endif
}
__attribute__((unused))
static inline
crypto_int32_unsigned crypto_int32_unsigned_topbit_01(crypto_int32_unsigned crypto_int32_x) {
#if defined(__GNUC__) && defined(__x86_64__)
__asm__ ("shrl $31,%0" : "+r"(crypto_int32_x) : : "cc");
return crypto_int32_x;
#elif defined(__GNUC__) && defined(__aarch64__)
crypto_int32 crypto_int32_y;
__asm__ ("lsr %w0,%w1,31" : "=r"(crypto_int32_y) : "r"(crypto_int32_x) : );
return crypto_int32_y;
#else
crypto_int32_x >>= 32-6;
crypto_int32_x ^= crypto_int32_optblocker;
crypto_int32_x >>= 5;
return crypto_int32_x;
#endif
}
__attribute__((unused))
static inline
crypto_int32 crypto_int32_negative_01(crypto_int32 crypto_int32_x) {
return crypto_int32_unsigned_topbit_01(crypto_int32_x);
}
__attribute__((unused))
static inline
crypto_int32 crypto_int32_topbit_mask(crypto_int32 crypto_int32_x) {
return crypto_int32_negative_mask(crypto_int32_x);
}
__attribute__((unused))
static inline
crypto_int32 crypto_int32_topbit_01(crypto_int32 crypto_int32_x) {
return crypto_int32_unsigned_topbit_01(crypto_int32_x);
}
__attribute__((unused))
static inline
crypto_int32 crypto_int32_bottombit_mask(crypto_int32 crypto_int32_x) {
#if defined(__GNUC__) && defined(__x86_64__)
__asm__ ("andl $1,%0" : "+r"(crypto_int32_x) : : "cc");
return -crypto_int32_x;
#elif defined(__GNUC__) && defined(__aarch64__)
crypto_int32 crypto_int32_y;
__asm__ ("sbfx %w0,%w1,0,1" : "=r"(crypto_int32_y) : "r"(crypto_int32_x) : );
return crypto_int32_y;
#else
crypto_int32_x &= 1 ^ crypto_int32_optblocker;
return -crypto_int32_x;
#endif
}
__attribute__((unused))
static inline
crypto_int32 crypto_int32_bottombit_01(crypto_int32 crypto_int32_x) {
#if defined(__GNUC__) && defined(__x86_64__)
__asm__ ("andl $1,%0" : "+r"(crypto_int32_x) : : "cc");
return crypto_int32_x;
#elif defined(__GNUC__) && defined(__aarch64__)
crypto_int32 crypto_int32_y;
__asm__ ("ubfx %w0,%w1,0,1" : "=r"(crypto_int32_y) : "r"(crypto_int32_x) : );
return crypto_int32_y;
#else
crypto_int32_x &= 1 ^ crypto_int32_optblocker;
return crypto_int32_x;
#endif
}
__attribute__((unused))
static inline
crypto_int32 crypto_int32_bitinrangepublicpos_mask(crypto_int32 crypto_int32_x,crypto_int32 crypto_int32_s) {
#if defined(__GNUC__) && defined(__x86_64__)
__asm__ ("sarl %%cl,%0" : "+r"(crypto_int32_x) : "c"(crypto_int32_s) : "cc");
#elif defined(__GNUC__) && defined(__aarch64__)
__asm__ ("asr %w0,%w0,%w1" : "+r"(crypto_int32_x) : "r"(crypto_int32_s) : );
#else
crypto_int32_x >>= crypto_int32_s ^ crypto_int32_optblocker;
#endif
return crypto_int32_bottombit_mask(crypto_int32_x);
}
__attribute__((unused))
static inline
crypto_int32 crypto_int32_bitinrangepublicpos_01(crypto_int32 crypto_int32_x,crypto_int32 crypto_int32_s) {
#if defined(__GNUC__) && defined(__x86_64__)
__asm__ ("sarl %%cl,%0" : "+r"(crypto_int32_x) : "c"(crypto_int32_s) : "cc");
#elif defined(__GNUC__) && defined(__aarch64__)
__asm__ ("asr %w0,%w0,%w1" : "+r"(crypto_int32_x) : "r"(crypto_int32_s) : );
#else
crypto_int32_x >>= crypto_int32_s ^ crypto_int32_optblocker;
#endif
return crypto_int32_bottombit_01(crypto_int32_x);
}
__attribute__((unused))
static inline
crypto_int32 crypto_int32_shlmod(crypto_int32 crypto_int32_x,crypto_int32 crypto_int32_s) {
#if defined(__GNUC__) && defined(__x86_64__)
__asm__ ("shll %%cl,%0" : "+r"(crypto_int32_x) : "c"(crypto_int32_s) : "cc");
#elif defined(__GNUC__) && defined(__aarch64__)
__asm__ ("lsl %w0,%w0,%w1" : "+r"(crypto_int32_x) : "r"(crypto_int32_s) : );
#else
int crypto_int32_k, crypto_int32_l;
for (crypto_int32_l = 0,crypto_int32_k = 1;crypto_int32_k < 32;++crypto_int32_l,crypto_int32_k *= 2)
crypto_int32_x ^= (crypto_int32_x ^ (crypto_int32_x << crypto_int32_k)) & crypto_int32_bitinrangepublicpos_mask(crypto_int32_s,crypto_int32_l);
#endif
return crypto_int32_x;
}
__attribute__((unused))
static inline
crypto_int32 crypto_int32_shrmod(crypto_int32 crypto_int32_x,crypto_int32 crypto_int32_s) {
#if defined(__GNUC__) && defined(__x86_64__)
__asm__ ("sarl %%cl,%0" : "+r"(crypto_int32_x) : "c"(crypto_int32_s) : "cc");
#elif defined(__GNUC__) && defined(__aarch64__)
__asm__ ("asr %w0,%w0,%w1" : "+r"(crypto_int32_x) : "r"(crypto_int32_s) : );
#else
int crypto_int32_k, crypto_int32_l;
for (crypto_int32_l = 0,crypto_int32_k = 1;crypto_int32_k < 32;++crypto_int32_l,crypto_int32_k *= 2)
crypto_int32_x ^= (crypto_int32_x ^ (crypto_int32_x >> crypto_int32_k)) & crypto_int32_bitinrangepublicpos_mask(crypto_int32_s,crypto_int32_l);
#endif
return crypto_int32_x;
}
__attribute__((unused))
static inline
crypto_int32 crypto_int32_bitmod_mask(crypto_int32 crypto_int32_x,crypto_int32 crypto_int32_s) {
crypto_int32_x = crypto_int32_shrmod(crypto_int32_x,crypto_int32_s);
return crypto_int32_bottombit_mask(crypto_int32_x);
}
__attribute__((unused))
static inline
crypto_int32 crypto_int32_bitmod_01(crypto_int32 crypto_int32_x,crypto_int32 crypto_int32_s) {
crypto_int32_x = crypto_int32_shrmod(crypto_int32_x,crypto_int32_s);
return crypto_int32_bottombit_01(crypto_int32_x);
}
__attribute__((unused))
static inline
crypto_int32 crypto_int32_nonzero_mask(crypto_int32 crypto_int32_x) {
#if defined(__GNUC__) && defined(__x86_64__)
crypto_int32 crypto_int32_q,crypto_int32_z;
__asm__ ("xorl %0,%0\n movl $-1,%1\n testl %2,%2\n cmovnel %1,%0" : "=&r"(crypto_int32_z), "=&r"(crypto_int32_q) : "r"(crypto_int32_x) : "cc");
return crypto_int32_z;
#elif defined(__GNUC__) && defined(__aarch64__)
crypto_int32 crypto_int32_z;
__asm__ ("cmp %w1,0\n csetm %w0,ne" : "=r"(crypto_int32_z) : "r"(crypto_int32_x) : "cc");
return crypto_int32_z;
#else
crypto_int32_x |= -crypto_int32_x;
return crypto_int32_negative_mask(crypto_int32_x);
#endif
}
__attribute__((unused))
static inline
crypto_int32 crypto_int32_nonzero_01(crypto_int32 crypto_int32_x) {
#if defined(__GNUC__) && defined(__x86_64__)
crypto_int32 crypto_int32_q,crypto_int32_z;
__asm__ ("xorl %0,%0\n movl $1,%1\n testl %2,%2\n cmovnel %1,%0" : "=&r"(crypto_int32_z), "=&r"(crypto_int32_q) : "r"(crypto_int32_x) : "cc");
return crypto_int32_z;
#elif defined(__GNUC__) && defined(__aarch64__)
crypto_int32 crypto_int32_z;
__asm__ ("cmp %w1,0\n cset %w0,ne" : "=r"(crypto_int32_z) : "r"(crypto_int32_x) : "cc");
return crypto_int32_z;
#else
crypto_int32_x |= -crypto_int32_x;
return crypto_int32_unsigned_topbit_01(crypto_int32_x);
#endif
}
__attribute__((unused))
static inline
crypto_int32 crypto_int32_positive_mask(crypto_int32 crypto_int32_x) {
#if defined(__GNUC__) && defined(__x86_64__)
crypto_int32 crypto_int32_q,crypto_int32_z;
__asm__ ("xorl %0,%0\n movl $-1,%1\n testl %2,%2\n cmovgl %1,%0" : "=&r"(crypto_int32_z), "=&r"(crypto_int32_q) : "r"(crypto_int32_x) : "cc");
return crypto_int32_z;
#elif defined(__GNUC__) && defined(__aarch64__)
crypto_int32 crypto_int32_z;
__asm__ ("cmp %w1,0\n csetm %w0,gt" : "=r"(crypto_int32_z) : "r"(crypto_int32_x) : "cc");
return crypto_int32_z;
#else
crypto_int32 crypto_int32_z = -crypto_int32_x;
crypto_int32_z ^= crypto_int32_x & crypto_int32_z;
return crypto_int32_negative_mask(crypto_int32_z);
#endif
}
__attribute__((unused))
static inline
crypto_int32 crypto_int32_positive_01(crypto_int32 crypto_int32_x) {
#if defined(__GNUC__) && defined(__x86_64__)
crypto_int32 crypto_int32_q,crypto_int32_z;
__asm__ ("xorl %0,%0\n movl $1,%1\n testl %2,%2\n cmovgl %1,%0" : "=&r"(crypto_int32_z), "=&r"(crypto_int32_q) : "r"(crypto_int32_x) : "cc");
return crypto_int32_z;
#elif defined(__GNUC__) && defined(__aarch64__)
crypto_int32 crypto_int32_z;
__asm__ ("cmp %w1,0\n cset %w0,gt" : "=r"(crypto_int32_z) : "r"(crypto_int32_x) : "cc");
return crypto_int32_z;
#else
crypto_int32 crypto_int32_z = -crypto_int32_x;
crypto_int32_z ^= crypto_int32_x & crypto_int32_z;
return crypto_int32_unsigned_topbit_01(crypto_int32_z);
#endif
}
__attribute__((unused))
static inline
crypto_int32 crypto_int32_zero_mask(crypto_int32 crypto_int32_x) {
#if defined(__GNUC__) && defined(__x86_64__)
crypto_int32 crypto_int32_q,crypto_int32_z;
__asm__ ("xorl %0,%0\n movl $-1,%1\n testl %2,%2\n cmovel %1,%0" : "=&r"(crypto_int32_z), "=&r"(crypto_int32_q) : "r"(crypto_int32_x) : "cc");
return crypto_int32_z;
#elif defined(__GNUC__) && defined(__aarch64__)
crypto_int32 crypto_int32_z;
__asm__ ("cmp %w1,0\n csetm %w0,eq" : "=r"(crypto_int32_z) : "r"(crypto_int32_x) : "cc");
return crypto_int32_z;
#else
return ~crypto_int32_nonzero_mask(crypto_int32_x);
#endif
}
__attribute__((unused))
static inline
crypto_int32 crypto_int32_zero_01(crypto_int32 crypto_int32_x) {
#if defined(__GNUC__) && defined(__x86_64__)
crypto_int32 crypto_int32_q,crypto_int32_z;
__asm__ ("xorl %0,%0\n movl $1,%1\n testl %2,%2\n cmovel %1,%0" : "=&r"(crypto_int32_z), "=&r"(crypto_int32_q) : "r"(crypto_int32_x) : "cc");
return crypto_int32_z;
#elif defined(__GNUC__) && defined(__aarch64__)
crypto_int32 crypto_int32_z;
__asm__ ("cmp %w1,0\n cset %w0,eq" : "=r"(crypto_int32_z) : "r"(crypto_int32_x) : "cc");
return crypto_int32_z;
#else
return 1-crypto_int32_nonzero_01(crypto_int32_x);
#endif
}
__attribute__((unused))
static inline
crypto_int32 crypto_int32_unequal_mask(crypto_int32 crypto_int32_x,crypto_int32 crypto_int32_y) {
#if defined(__GNUC__) && defined(__x86_64__)
crypto_int32 crypto_int32_q,crypto_int32_z;
__asm__ ("xorl %0,%0\n movl $-1,%1\n cmpl %3,%2\n cmovnel %1,%0" : "=&r"(crypto_int32_z), "=&r"(crypto_int32_q) : "r"(crypto_int32_x), "r"(crypto_int32_y) : "cc");
return crypto_int32_z;
#elif defined(__GNUC__) && defined(__aarch64__)
crypto_int32 crypto_int32_z;
__asm__ ("cmp %w1,%w2\n csetm %w0,ne" : "=r"(crypto_int32_z) : "r"(crypto_int32_x), "r"(crypto_int32_y) : "cc");
return crypto_int32_z;
#else
return crypto_int32_nonzero_mask(crypto_int32_x ^ crypto_int32_y);
#endif
}
__attribute__((unused))
static inline
crypto_int32 crypto_int32_unequal_01(crypto_int32 crypto_int32_x,crypto_int32 crypto_int32_y) {
#if defined(__GNUC__) && defined(__x86_64__)
crypto_int32 crypto_int32_q,crypto_int32_z;
__asm__ ("xorl %0,%0\n movl $1,%1\n cmpl %3,%2\n cmovnel %1,%0" : "=&r"(crypto_int32_z), "=&r"(crypto_int32_q) : "r"(crypto_int32_x), "r"(crypto_int32_y) : "cc");
return crypto_int32_z;
#elif defined(__GNUC__) && defined(__aarch64__)
crypto_int32 crypto_int32_z;
__asm__ ("cmp %w1,%w2\n cset %w0,ne" : "=r"(crypto_int32_z) : "r"(crypto_int32_x), "r"(crypto_int32_y) : "cc");
return crypto_int32_z;
#else
return crypto_int32_nonzero_01(crypto_int32_x ^ crypto_int32_y);
#endif
}
__attribute__((unused))
static inline
crypto_int32 crypto_int32_equal_mask(crypto_int32 crypto_int32_x,crypto_int32 crypto_int32_y) {
#if defined(__GNUC__) && defined(__x86_64__)
crypto_int32 crypto_int32_q,crypto_int32_z;
__asm__ ("xorl %0,%0\n movl $-1,%1\n cmpl %3,%2\n cmovel %1,%0" : "=&r"(crypto_int32_z), "=&r"(crypto_int32_q) : "r"(crypto_int32_x), "r"(crypto_int32_y) : "cc");
return crypto_int32_z;
#elif defined(__GNUC__) && defined(__aarch64__)
crypto_int32 crypto_int32_z;
__asm__ ("cmp %w1,%w2\n csetm %w0,eq" : "=r"(crypto_int32_z) : "r"(crypto_int32_x), "r"(crypto_int32_y) : "cc");
return crypto_int32_z;
#else
return ~crypto_int32_unequal_mask(crypto_int32_x,crypto_int32_y);
#endif
}
__attribute__((unused))
static inline
crypto_int32 crypto_int32_equal_01(crypto_int32 crypto_int32_x,crypto_int32 crypto_int32_y) {
#if defined(__GNUC__) && defined(__x86_64__)
crypto_int32 crypto_int32_q,crypto_int32_z;
__asm__ ("xorl %0,%0\n movl $1,%1\n cmpl %3,%2\n cmovel %1,%0" : "=&r"(crypto_int32_z), "=&r"(crypto_int32_q) : "r"(crypto_int32_x), "r"(crypto_int32_y) : "cc");
return crypto_int32_z;
#elif defined(__GNUC__) && defined(__aarch64__)
crypto_int32 crypto_int32_z;
__asm__ ("cmp %w1,%w2\n cset %w0,eq" : "=r"(crypto_int32_z) : "r"(crypto_int32_x), "r"(crypto_int32_y) : "cc");
return crypto_int32_z;
#else
return 1-crypto_int32_unequal_01(crypto_int32_x,crypto_int32_y);
#endif
}
__attribute__((unused))
static inline
crypto_int32 crypto_int32_min(crypto_int32 crypto_int32_x,crypto_int32 crypto_int32_y) {
#if defined(__GNUC__) && defined(__x86_64__)
__asm__ ("cmpl %1,%0\n cmovgl %1,%0" : "+r"(crypto_int32_x) : "r"(crypto_int32_y) : "cc");
return crypto_int32_x;
#elif defined(__GNUC__) && defined(__aarch64__)
__asm__ ("cmp %w0,%w1\n csel %w0,%w0,%w1,lt" : "+r"(crypto_int32_x) : "r"(crypto_int32_y) : "cc");
return crypto_int32_x;
#else
crypto_int64 crypto_int32_r = (crypto_int64)crypto_int32_y ^ (crypto_int64)crypto_int32_x;
crypto_int64 crypto_int32_z = (crypto_int64)crypto_int32_y - (crypto_int64)crypto_int32_x;
crypto_int32_z ^= crypto_int32_r & (crypto_int32_z ^ crypto_int32_y);
crypto_int32_z = crypto_int32_negative_mask(crypto_int32_z);
crypto_int32_z &= crypto_int32_r;
return crypto_int32_x ^ crypto_int32_z;
#endif
}
__attribute__((unused))
static inline
crypto_int32 crypto_int32_max(crypto_int32 crypto_int32_x,crypto_int32 crypto_int32_y) {
#if defined(__GNUC__) && defined(__x86_64__)
__asm__ ("cmpl %1,%0\n cmovll %1,%0" : "+r"(crypto_int32_x) : "r"(crypto_int32_y) : "cc");
return crypto_int32_x;
#elif defined(__GNUC__) && defined(__aarch64__)
__asm__ ("cmp %w0,%w1\n csel %w0,%w1,%w0,lt" : "+r"(crypto_int32_x) : "r"(crypto_int32_y) : "cc");
return crypto_int32_x;
#else
crypto_int64 crypto_int32_r = (crypto_int64)crypto_int32_y ^ (crypto_int64)crypto_int32_x;
crypto_int64 crypto_int32_z = (crypto_int64)crypto_int32_y - (crypto_int64)crypto_int32_x;
crypto_int32_z ^= crypto_int32_r & (crypto_int32_z ^ crypto_int32_y);
crypto_int32_z = crypto_int32_negative_mask(crypto_int32_z);
crypto_int32_z &= crypto_int32_r;
return crypto_int32_y ^ crypto_int32_z;
#endif
}
__attribute__((unused))
static inline
void crypto_int32_minmax(crypto_int32 *crypto_int32_p,crypto_int32 *crypto_int32_q) {
crypto_int32 crypto_int32_x = *crypto_int32_p;
crypto_int32 crypto_int32_y = *crypto_int32_q;
#if defined(__GNUC__) && defined(__x86_64__)
crypto_int32 crypto_int32_z;
__asm__ ("cmpl %2,%1\n movl %1,%0\n cmovgl %2,%1\n cmovgl %0,%2" : "=&r"(crypto_int32_z), "+&r"(crypto_int32_x), "+r"(crypto_int32_y) : : "cc");
*crypto_int32_p = crypto_int32_x;
*crypto_int32_q = crypto_int32_y;
#elif defined(__GNUC__) && defined(__aarch64__)
crypto_int32 crypto_int32_r, crypto_int32_s;
__asm__ ("cmp %w2,%w3\n csel %w0,%w2,%w3,lt\n csel %w1,%w3,%w2,lt" : "=&r"(crypto_int32_r), "=r"(crypto_int32_s) : "r"(crypto_int32_x), "r"(crypto_int32_y) : "cc");
*crypto_int32_p = crypto_int32_r;
*crypto_int32_q = crypto_int32_s;
#else
crypto_int64 crypto_int32_r = (crypto_int64)crypto_int32_y ^ (crypto_int64)crypto_int32_x;
crypto_int64 crypto_int32_z = (crypto_int64)crypto_int32_y - (crypto_int64)crypto_int32_x;
crypto_int32_z ^= crypto_int32_r & (crypto_int32_z ^ crypto_int32_y);
crypto_int32_z = crypto_int32_negative_mask(crypto_int32_z);
crypto_int32_z &= crypto_int32_r;
crypto_int32_x ^= crypto_int32_z;
crypto_int32_y ^= crypto_int32_z;
*crypto_int32_p = crypto_int32_x;
*crypto_int32_q = crypto_int32_y;
#endif
}
__attribute__((unused))
static inline
crypto_int32 crypto_int32_smaller_mask(crypto_int32 crypto_int32_x,crypto_int32 crypto_int32_y) {
#if defined(__GNUC__) && defined(__x86_64__)
crypto_int32 crypto_int32_q,crypto_int32_z;
__asm__ ("xorl %0,%0\n movl $-1,%1\n cmpl %3,%2\n cmovll %1,%0" : "=&r"(crypto_int32_z), "=&r"(crypto_int32_q) : "r"(crypto_int32_x), "r"(crypto_int32_y) : "cc");
return crypto_int32_z;
#elif defined(__GNUC__) && defined(__aarch64__)
crypto_int32 crypto_int32_z;
__asm__ ("cmp %w1,%w2\n csetm %w0,lt" : "=r"(crypto_int32_z) : "r"(crypto_int32_x), "r"(crypto_int32_y) : "cc");
return crypto_int32_z;
#else
crypto_int32 crypto_int32_r = crypto_int32_x ^ crypto_int32_y;
crypto_int32 crypto_int32_z = crypto_int32_x - crypto_int32_y;
crypto_int32_z ^= crypto_int32_r & (crypto_int32_z ^ crypto_int32_x);
return crypto_int32_negative_mask(crypto_int32_z);
#endif
}
__attribute__((unused))
static inline
crypto_int32 crypto_int32_smaller_01(crypto_int32 crypto_int32_x,crypto_int32 crypto_int32_y) {
#if defined(__GNUC__) && defined(__x86_64__)
crypto_int32 crypto_int32_q,crypto_int32_z;
__asm__ ("xorl %0,%0\n movl $1,%1\n cmpl %3,%2\n cmovll %1,%0" : "=&r"(crypto_int32_z), "=&r"(crypto_int32_q) : "r"(crypto_int32_x), "r"(crypto_int32_y) : "cc");
return crypto_int32_z;
#elif defined(__GNUC__) && defined(__aarch64__)
crypto_int32 crypto_int32_z;
__asm__ ("cmp %w1,%w2\n cset %w0,lt" : "=r"(crypto_int32_z) : "r"(crypto_int32_x), "r"(crypto_int32_y) : "cc");
return crypto_int32_z;
#else
crypto_int32 crypto_int32_r = crypto_int32_x ^ crypto_int32_y;
crypto_int32 crypto_int32_z = crypto_int32_x - crypto_int32_y;
crypto_int32_z ^= crypto_int32_r & (crypto_int32_z ^ crypto_int32_x);
return crypto_int32_unsigned_topbit_01(crypto_int32_z);
#endif
}
__attribute__((unused))
static inline
crypto_int32 crypto_int32_leq_mask(crypto_int32 crypto_int32_x,crypto_int32 crypto_int32_y) {
#if defined(__GNUC__) && defined(__x86_64__)
crypto_int32 crypto_int32_q,crypto_int32_z;
__asm__ ("xorl %0,%0\n movl $-1,%1\n cmpl %3,%2\n cmovlel %1,%0" : "=&r"(crypto_int32_z), "=&r"(crypto_int32_q) : "r"(crypto_int32_x), "r"(crypto_int32_y) : "cc");
return crypto_int32_z;
#elif defined(__GNUC__) && defined(__aarch64__)
crypto_int32 crypto_int32_z;
__asm__ ("cmp %w1,%w2\n csetm %w0,le" : "=r"(crypto_int32_z) : "r"(crypto_int32_x), "r"(crypto_int32_y) : "cc");
return crypto_int32_z;
#else
return ~crypto_int32_smaller_mask(crypto_int32_y,crypto_int32_x);
#endif
}
__attribute__((unused))
static inline
crypto_int32 crypto_int32_leq_01(crypto_int32 crypto_int32_x,crypto_int32 crypto_int32_y) {
#if defined(__GNUC__) && defined(__x86_64__)
crypto_int32 crypto_int32_q,crypto_int32_z;
__asm__ ("xorl %0,%0\n movl $1,%1\n cmpl %3,%2\n cmovlel %1,%0" : "=&r"(crypto_int32_z), "=&r"(crypto_int32_q) : "r"(crypto_int32_x), "r"(crypto_int32_y) : "cc");
return crypto_int32_z;
#elif defined(__GNUC__) && defined(__aarch64__)
crypto_int32 crypto_int32_z;
__asm__ ("cmp %w1,%w2\n cset %w0,le" : "=r"(crypto_int32_z) : "r"(crypto_int32_x), "r"(crypto_int32_y) : "cc");
return crypto_int32_z;
#else
return 1-crypto_int32_smaller_01(crypto_int32_y,crypto_int32_x);
#endif
}
__attribute__((unused))
static inline
int crypto_int32_ones_num(crypto_int32 crypto_int32_x) {
crypto_int32_unsigned crypto_int32_y = crypto_int32_x;
const crypto_int32 C0 = 0x55555555;
const crypto_int32 C1 = 0x33333333;
const crypto_int32 C2 = 0x0f0f0f0f;
crypto_int32_y -= ((crypto_int32_y >> 1) & C0);
crypto_int32_y = (crypto_int32_y & C1) + ((crypto_int32_y >> 2) & C1);
crypto_int32_y = (crypto_int32_y + (crypto_int32_y >> 4)) & C2;
crypto_int32_y += crypto_int32_y >> 8;
crypto_int32_y = (crypto_int32_y + (crypto_int32_y >> 16)) & 0xff;
return crypto_int32_y;
}
__attribute__((unused))
static inline
int crypto_int32_bottomzeros_num(crypto_int32 crypto_int32_x) {
#if defined(__GNUC__) && defined(__x86_64__)
crypto_int32 fallback = 32;
__asm__ ("bsfl %0,%0\n cmovel %1,%0" : "+&r"(crypto_int32_x) : "r"(fallback) : "cc");
return crypto_int32_x;
#elif defined(__GNUC__) && defined(__aarch64__)
int64_t crypto_int32_y;
__asm__ ("rbit %w0,%w1\n clz %w0,%w0" : "=r"(crypto_int32_y) : "r"(crypto_int32_x) : );
return crypto_int32_y;
#else
crypto_int32 crypto_int32_y = crypto_int32_x ^ (crypto_int32_x-1);
crypto_int32_y = ((crypto_int32) crypto_int32_y) >> 1;
crypto_int32_y &= ~(crypto_int32_x & (((crypto_int32) 1) << (32-1)));
return crypto_int32_ones_num(crypto_int32_y);
#endif
}
#endif
/* from supercop-20240808/cryptoint/crypto_int64.h */
/* auto-generated: cd cryptoint; ./autogen */
/* cryptoint 20240806 */
#ifndef crypto_int64_h
#define crypto_int64_h
#define crypto_int64 int64_t
#define crypto_int64_unsigned uint64_t
__attribute__((unused))
static inline
crypto_int64 crypto_int64_load(const unsigned char *crypto_int64_s) {
crypto_int64 crypto_int64_z = 0;
crypto_int64_z |= ((crypto_int64) (*crypto_int64_s++)) << 0;
crypto_int64_z |= ((crypto_int64) (*crypto_int64_s++)) << 8;
crypto_int64_z |= ((crypto_int64) (*crypto_int64_s++)) << 16;
crypto_int64_z |= ((crypto_int64) (*crypto_int64_s++)) << 24;
crypto_int64_z |= ((crypto_int64) (*crypto_int64_s++)) << 32;
crypto_int64_z |= ((crypto_int64) (*crypto_int64_s++)) << 40;
crypto_int64_z |= ((crypto_int64) (*crypto_int64_s++)) << 48;
crypto_int64_z |= ((crypto_int64) (*crypto_int64_s++)) << 56;
return crypto_int64_z;
}
__attribute__((unused))
static inline
void crypto_int64_store(unsigned char *crypto_int64_s,crypto_int64 crypto_int64_x) {
*crypto_int64_s++ = crypto_int64_x >> 0;
*crypto_int64_s++ = crypto_int64_x >> 8;
*crypto_int64_s++ = crypto_int64_x >> 16;
*crypto_int64_s++ = crypto_int64_x >> 24;
*crypto_int64_s++ = crypto_int64_x >> 32;
*crypto_int64_s++ = crypto_int64_x >> 40;
*crypto_int64_s++ = crypto_int64_x >> 48;
*crypto_int64_s++ = crypto_int64_x >> 56;
}
__attribute__((unused))
static inline
crypto_int64 crypto_int64_negative_mask(crypto_int64 crypto_int64_x) {
#if defined(__GNUC__) && defined(__x86_64__)
__asm__ ("sarq $63,%0" : "+r"(crypto_int64_x) : : "cc");
return crypto_int64_x;
#elif defined(__GNUC__) && defined(__aarch64__)
crypto_int64 crypto_int64_y;
__asm__ ("asr %0,%1,63" : "=r"(crypto_int64_y) : "r"(crypto_int64_x) : );
return crypto_int64_y;
#else
crypto_int64_x >>= 64-6;
crypto_int64_x ^= crypto_int64_optblocker;
crypto_int64_x >>= 5;
return crypto_int64_x;
#endif
}
__attribute__((unused))
static inline
crypto_int64_unsigned crypto_int64_unsigned_topbit_01(crypto_int64_unsigned crypto_int64_x) {
#if defined(__GNUC__) && defined(__x86_64__)
__asm__ ("shrq $63,%0" : "+r"(crypto_int64_x) : : "cc");
return crypto_int64_x;
#elif defined(__GNUC__) && defined(__aarch64__)
crypto_int64 crypto_int64_y;
__asm__ ("lsr %0,%1,63" : "=r"(crypto_int64_y) : "r"(crypto_int64_x) : );
return crypto_int64_y;
#else
crypto_int64_x >>= 64-6;
crypto_int64_x ^= crypto_int64_optblocker;
crypto_int64_x >>= 5;
return crypto_int64_x;
#endif
}
__attribute__((unused))
static inline
crypto_int64 crypto_int64_negative_01(crypto_int64 crypto_int64_x) {
return crypto_int64_unsigned_topbit_01(crypto_int64_x);
}
__attribute__((unused))
static inline
crypto_int64 crypto_int64_topbit_mask(crypto_int64 crypto_int64_x) {
return crypto_int64_negative_mask(crypto_int64_x);
}
__attribute__((unused))
static inline
crypto_int64 crypto_int64_topbit_01(crypto_int64 crypto_int64_x) {
return crypto_int64_unsigned_topbit_01(crypto_int64_x);
}
__attribute__((unused))
static inline
crypto_int64 crypto_int64_bottombit_mask(crypto_int64 crypto_int64_x) {
#if defined(__GNUC__) && defined(__x86_64__)
__asm__ ("andq $1,%0" : "+r"(crypto_int64_x) : : "cc");
return -crypto_int64_x;
#elif defined(__GNUC__) && defined(__aarch64__)
crypto_int64 crypto_int64_y;
__asm__ ("sbfx %0,%1,0,1" : "=r"(crypto_int64_y) : "r"(crypto_int64_x) : );
return crypto_int64_y;
#else
crypto_int64_x &= 1 ^ crypto_int64_optblocker;
return -crypto_int64_x;
#endif
}
__attribute__((unused))
static inline
crypto_int64 crypto_int64_bottombit_01(crypto_int64 crypto_int64_x) {
#if defined(__GNUC__) && defined(__x86_64__)
__asm__ ("andq $1,%0" : "+r"(crypto_int64_x) : : "cc");
return crypto_int64_x;
#elif defined(__GNUC__) && defined(__aarch64__)
crypto_int64 crypto_int64_y;
__asm__ ("ubfx %0,%1,0,1" : "=r"(crypto_int64_y) : "r"(crypto_int64_x) : );
return crypto_int64_y;
#else
crypto_int64_x &= 1 ^ crypto_int64_optblocker;
return crypto_int64_x;
#endif
}
__attribute__((unused))
static inline
crypto_int64 crypto_int64_bitinrangepublicpos_mask(crypto_int64 crypto_int64_x,crypto_int64 crypto_int64_s) {
#if defined(__GNUC__) && defined(__x86_64__)
__asm__ ("sarq %%cl,%0" : "+r"(crypto_int64_x) : "c"(crypto_int64_s) : "cc");
#elif defined(__GNUC__) && defined(__aarch64__)
__asm__ ("asr %0,%0,%1" : "+r"(crypto_int64_x) : "r"(crypto_int64_s) : );
#else
crypto_int64_x >>= crypto_int64_s ^ crypto_int64_optblocker;
#endif
return crypto_int64_bottombit_mask(crypto_int64_x);
}
__attribute__((unused))
static inline
crypto_int64 crypto_int64_bitinrangepublicpos_01(crypto_int64 crypto_int64_x,crypto_int64 crypto_int64_s) {
#if defined(__GNUC__) && defined(__x86_64__)
__asm__ ("sarq %%cl,%0" : "+r"(crypto_int64_x) : "c"(crypto_int64_s) : "cc");
#elif defined(__GNUC__) && defined(__aarch64__)
__asm__ ("asr %0,%0,%1" : "+r"(crypto_int64_x) : "r"(crypto_int64_s) : );
#else
crypto_int64_x >>= crypto_int64_s ^ crypto_int64_optblocker;
#endif
return crypto_int64_bottombit_01(crypto_int64_x);
}
__attribute__((unused))
static inline
crypto_int64 crypto_int64_shlmod(crypto_int64 crypto_int64_x,crypto_int64 crypto_int64_s) {
#if defined(__GNUC__) && defined(__x86_64__)
__asm__ ("shlq %%cl,%0" : "+r"(crypto_int64_x) : "c"(crypto_int64_s) : "cc");
#elif defined(__GNUC__) && defined(__aarch64__)
__asm__ ("lsl %0,%0,%1" : "+r"(crypto_int64_x) : "r"(crypto_int64_s) : );
#else
int crypto_int64_k, crypto_int64_l;
for (crypto_int64_l = 0,crypto_int64_k = 1;crypto_int64_k < 64;++crypto_int64_l,crypto_int64_k *= 2)
crypto_int64_x ^= (crypto_int64_x ^ (crypto_int64_x << crypto_int64_k)) & crypto_int64_bitinrangepublicpos_mask(crypto_int64_s,crypto_int64_l);
#endif
return crypto_int64_x;
}
__attribute__((unused))
static inline
crypto_int64 crypto_int64_shrmod(crypto_int64 crypto_int64_x,crypto_int64 crypto_int64_s) {
#if defined(__GNUC__) && defined(__x86_64__)
__asm__ ("sarq %%cl,%0" : "+r"(crypto_int64_x) : "c"(crypto_int64_s) : "cc");
#elif defined(__GNUC__) && defined(__aarch64__)
__asm__ ("asr %0,%0,%1" : "+r"(crypto_int64_x) : "r"(crypto_int64_s) : );
#else
int crypto_int64_k, crypto_int64_l;
for (crypto_int64_l = 0,crypto_int64_k = 1;crypto_int64_k < 64;++crypto_int64_l,crypto_int64_k *= 2)
crypto_int64_x ^= (crypto_int64_x ^ (crypto_int64_x >> crypto_int64_k)) & crypto_int64_bitinrangepublicpos_mask(crypto_int64_s,crypto_int64_l);
#endif
return crypto_int64_x;
}
__attribute__((unused))
static inline
crypto_int64 crypto_int64_bitmod_mask(crypto_int64 crypto_int64_x,crypto_int64 crypto_int64_s) {
crypto_int64_x = crypto_int64_shrmod(crypto_int64_x,crypto_int64_s);
return crypto_int64_bottombit_mask(crypto_int64_x);
}
__attribute__((unused))
static inline
crypto_int64 crypto_int64_bitmod_01(crypto_int64 crypto_int64_x,crypto_int64 crypto_int64_s) {
crypto_int64_x = crypto_int64_shrmod(crypto_int64_x,crypto_int64_s);
return crypto_int64_bottombit_01(crypto_int64_x);
}
__attribute__((unused))
static inline
crypto_int64 crypto_int64_nonzero_mask(crypto_int64 crypto_int64_x) {
#if defined(__GNUC__) && defined(__x86_64__)
crypto_int64 crypto_int64_q,crypto_int64_z;
__asm__ ("xorq %0,%0\n movq $-1,%1\n testq %2,%2\n cmovneq %1,%0" : "=&r"(crypto_int64_z), "=&r"(crypto_int64_q) : "r"(crypto_int64_x) : "cc");
return crypto_int64_z;
#elif defined(__GNUC__) && defined(__aarch64__)
crypto_int64 crypto_int64_z;
__asm__ ("cmp %1,0\n csetm %0,ne" : "=r"(crypto_int64_z) : "r"(crypto_int64_x) : "cc");
return crypto_int64_z;
#else
crypto_int64_x |= -crypto_int64_x;
return crypto_int64_negative_mask(crypto_int64_x);
#endif
}
__attribute__((unused))
static inline
crypto_int64 crypto_int64_nonzero_01(crypto_int64 crypto_int64_x) {
#if defined(__GNUC__) && defined(__x86_64__)
crypto_int64 crypto_int64_q,crypto_int64_z;
__asm__ ("xorq %0,%0\n movq $1,%1\n testq %2,%2\n cmovneq %1,%0" : "=&r"(crypto_int64_z), "=&r"(crypto_int64_q) : "r"(crypto_int64_x) : "cc");
return crypto_int64_z;
#elif defined(__GNUC__) && defined(__aarch64__)
crypto_int64 crypto_int64_z;
__asm__ ("cmp %1,0\n cset %0,ne" : "=r"(crypto_int64_z) : "r"(crypto_int64_x) : "cc");
return crypto_int64_z;
#else
crypto_int64_x |= -crypto_int64_x;
return crypto_int64_unsigned_topbit_01(crypto_int64_x);
#endif
}
__attribute__((unused))
static inline
crypto_int64 crypto_int64_positive_mask(crypto_int64 crypto_int64_x) {
#if defined(__GNUC__) && defined(__x86_64__)
crypto_int64 crypto_int64_q,crypto_int64_z;
__asm__ ("xorq %0,%0\n movq $-1,%1\n testq %2,%2\n cmovgq %1,%0" : "=&r"(crypto_int64_z), "=&r"(crypto_int64_q) : "r"(crypto_int64_x) : "cc");
return crypto_int64_z;
#elif defined(__GNUC__) && defined(__aarch64__)
crypto_int64 crypto_int64_z;
__asm__ ("cmp %1,0\n csetm %0,gt" : "=r"(crypto_int64_z) : "r"(crypto_int64_x) : "cc");
return crypto_int64_z;
#else
crypto_int64 crypto_int64_z = -crypto_int64_x;
crypto_int64_z ^= crypto_int64_x & crypto_int64_z;
return crypto_int64_negative_mask(crypto_int64_z);
#endif
}
__attribute__((unused))
static inline
crypto_int64 crypto_int64_positive_01(crypto_int64 crypto_int64_x) {
#if defined(__GNUC__) && defined(__x86_64__)
crypto_int64 crypto_int64_q,crypto_int64_z;
__asm__ ("xorq %0,%0\n movq $1,%1\n testq %2,%2\n cmovgq %1,%0" : "=&r"(crypto_int64_z), "=&r"(crypto_int64_q) : "r"(crypto_int64_x) : "cc");
return crypto_int64_z;
#elif defined(__GNUC__) && defined(__aarch64__)
crypto_int64 crypto_int64_z;
__asm__ ("cmp %1,0\n cset %0,gt" : "=r"(crypto_int64_z) : "r"(crypto_int64_x) : "cc");
return crypto_int64_z;
#else
crypto_int64 crypto_int64_z = -crypto_int64_x;
crypto_int64_z ^= crypto_int64_x & crypto_int64_z;
return crypto_int64_unsigned_topbit_01(crypto_int64_z);
#endif
}
__attribute__((unused))
static inline
crypto_int64 crypto_int64_zero_mask(crypto_int64 crypto_int64_x) {
#if defined(__GNUC__) && defined(__x86_64__)
crypto_int64 crypto_int64_q,crypto_int64_z;
__asm__ ("xorq %0,%0\n movq $-1,%1\n testq %2,%2\n cmoveq %1,%0" : "=&r"(crypto_int64_z), "=&r"(crypto_int64_q) : "r"(crypto_int64_x) : "cc");
return crypto_int64_z;
#elif defined(__GNUC__) && defined(__aarch64__)
crypto_int64 crypto_int64_z;
__asm__ ("cmp %1,0\n csetm %0,eq" : "=r"(crypto_int64_z) : "r"(crypto_int64_x) : "cc");
return crypto_int64_z;
#else
return ~crypto_int64_nonzero_mask(crypto_int64_x);
#endif
}
__attribute__((unused))
static inline
crypto_int64 crypto_int64_zero_01(crypto_int64 crypto_int64_x) {
#if defined(__GNUC__) && defined(__x86_64__)
crypto_int64 crypto_int64_q,crypto_int64_z;
__asm__ ("xorq %0,%0\n movq $1,%1\n testq %2,%2\n cmoveq %1,%0" : "=&r"(crypto_int64_z), "=&r"(crypto_int64_q) : "r"(crypto_int64_x) : "cc");
return crypto_int64_z;
#elif defined(__GNUC__) && defined(__aarch64__)
crypto_int64 crypto_int64_z;
__asm__ ("cmp %1,0\n cset %0,eq" : "=r"(crypto_int64_z) : "r"(crypto_int64_x) : "cc");
return crypto_int64_z;
#else
return 1-crypto_int64_nonzero_01(crypto_int64_x);
#endif
}
__attribute__((unused))
static inline
crypto_int64 crypto_int64_unequal_mask(crypto_int64 crypto_int64_x,crypto_int64 crypto_int64_y) {
#if defined(__GNUC__) && defined(__x86_64__)
crypto_int64 crypto_int64_q,crypto_int64_z;
__asm__ ("xorq %0,%0\n movq $-1,%1\n cmpq %3,%2\n cmovneq %1,%0" : "=&r"(crypto_int64_z), "=&r"(crypto_int64_q) : "r"(crypto_int64_x), "r"(crypto_int64_y) : "cc");
return crypto_int64_z;
#elif defined(__GNUC__) && defined(__aarch64__)
crypto_int64 crypto_int64_z;
__asm__ ("cmp %1,%2\n csetm %0,ne" : "=r"(crypto_int64_z) : "r"(crypto_int64_x), "r"(crypto_int64_y) : "cc");
return crypto_int64_z;
#else
return crypto_int64_nonzero_mask(crypto_int64_x ^ crypto_int64_y);
#endif
}
__attribute__((unused))
static inline
crypto_int64 crypto_int64_unequal_01(crypto_int64 crypto_int64_x,crypto_int64 crypto_int64_y) {
#if defined(__GNUC__) && defined(__x86_64__)
crypto_int64 crypto_int64_q,crypto_int64_z;
__asm__ ("xorq %0,%0\n movq $1,%1\n cmpq %3,%2\n cmovneq %1,%0" : "=&r"(crypto_int64_z), "=&r"(crypto_int64_q) : "r"(crypto_int64_x), "r"(crypto_int64_y) : "cc");
return crypto_int64_z;
#elif defined(__GNUC__) && defined(__aarch64__)
crypto_int64 crypto_int64_z;
__asm__ ("cmp %1,%2\n cset %0,ne" : "=r"(crypto_int64_z) : "r"(crypto_int64_x), "r"(crypto_int64_y) : "cc");
return crypto_int64_z;
#else
return crypto_int64_nonzero_01(crypto_int64_x ^ crypto_int64_y);
#endif
}
__attribute__((unused))
static inline
crypto_int64 crypto_int64_equal_mask(crypto_int64 crypto_int64_x,crypto_int64 crypto_int64_y) {
#if defined(__GNUC__) && defined(__x86_64__)
crypto_int64 crypto_int64_q,crypto_int64_z;
__asm__ ("xorq %0,%0\n movq $-1,%1\n cmpq %3,%2\n cmoveq %1,%0" : "=&r"(crypto_int64_z), "=&r"(crypto_int64_q) : "r"(crypto_int64_x), "r"(crypto_int64_y) : "cc");
return crypto_int64_z;
#elif defined(__GNUC__) && defined(__aarch64__)
crypto_int64 crypto_int64_z;
__asm__ ("cmp %1,%2\n csetm %0,eq" : "=r"(crypto_int64_z) : "r"(crypto_int64_x), "r"(crypto_int64_y) : "cc");
return crypto_int64_z;
#else
return ~crypto_int64_unequal_mask(crypto_int64_x,crypto_int64_y);
#endif
}
__attribute__((unused))
static inline
crypto_int64 crypto_int64_equal_01(crypto_int64 crypto_int64_x,crypto_int64 crypto_int64_y) {
#if defined(__GNUC__) && defined(__x86_64__)
crypto_int64 crypto_int64_q,crypto_int64_z;
__asm__ ("xorq %0,%0\n movq $1,%1\n cmpq %3,%2\n cmoveq %1,%0" : "=&r"(crypto_int64_z), "=&r"(crypto_int64_q) : "r"(crypto_int64_x), "r"(crypto_int64_y) : "cc");
return crypto_int64_z;
#elif defined(__GNUC__) && defined(__aarch64__)
crypto_int64 crypto_int64_z;
__asm__ ("cmp %1,%2\n cset %0,eq" : "=r"(crypto_int64_z) : "r"(crypto_int64_x), "r"(crypto_int64_y) : "cc");
return crypto_int64_z;
#else
return 1-crypto_int64_unequal_01(crypto_int64_x,crypto_int64_y);
#endif
}
__attribute__((unused))
static inline
crypto_int64 crypto_int64_min(crypto_int64 crypto_int64_x,crypto_int64 crypto_int64_y) {
#if defined(__GNUC__) && defined(__x86_64__)
__asm__ ("cmpq %1,%0\n cmovgq %1,%0" : "+r"(crypto_int64_x) : "r"(crypto_int64_y) : "cc");
return crypto_int64_x;
#elif defined(__GNUC__) && defined(__aarch64__)
__asm__ ("cmp %0,%1\n csel %0,%0,%1,lt" : "+r"(crypto_int64_x) : "r"(crypto_int64_y) : "cc");
return crypto_int64_x;
#else
crypto_int64 crypto_int64_r = crypto_int64_y ^ crypto_int64_x;
crypto_int64 crypto_int64_z = crypto_int64_y - crypto_int64_x;
crypto_int64_z ^= crypto_int64_r & (crypto_int64_z ^ crypto_int64_y);
crypto_int64_z = crypto_int64_negative_mask(crypto_int64_z);
crypto_int64_z &= crypto_int64_r;
return crypto_int64_x ^ crypto_int64_z;
#endif
}
__attribute__((unused))
static inline
crypto_int64 crypto_int64_max(crypto_int64 crypto_int64_x,crypto_int64 crypto_int64_y) {
#if defined(__GNUC__) && defined(__x86_64__)
__asm__ ("cmpq %1,%0\n cmovlq %1,%0" : "+r"(crypto_int64_x) : "r"(crypto_int64_y) : "cc");
return crypto_int64_x;
#elif defined(__GNUC__) && defined(__aarch64__)
__asm__ ("cmp %0,%1\n csel %0,%1,%0,lt" : "+r"(crypto_int64_x) : "r"(crypto_int64_y) : "cc");
return crypto_int64_x;
#else
crypto_int64 crypto_int64_r = crypto_int64_y ^ crypto_int64_x;
crypto_int64 crypto_int64_z = crypto_int64_y - crypto_int64_x;
crypto_int64_z ^= crypto_int64_r & (crypto_int64_z ^ crypto_int64_y);
crypto_int64_z = crypto_int64_negative_mask(crypto_int64_z);
crypto_int64_z &= crypto_int64_r;
return crypto_int64_y ^ crypto_int64_z;
#endif
}
__attribute__((unused))
static inline
void crypto_int64_minmax(crypto_int64 *crypto_int64_p,crypto_int64 *crypto_int64_q) {
crypto_int64 crypto_int64_x = *crypto_int64_p;
crypto_int64 crypto_int64_y = *crypto_int64_q;
#if defined(__GNUC__) && defined(__x86_64__)
crypto_int64 crypto_int64_z;
__asm__ ("cmpq %2,%1\n movq %1,%0\n cmovgq %2,%1\n cmovgq %0,%2" : "=&r"(crypto_int64_z), "+&r"(crypto_int64_x), "+r"(crypto_int64_y) : : "cc");
*crypto_int64_p = crypto_int64_x;
*crypto_int64_q = crypto_int64_y;
#elif defined(__GNUC__) && defined(__aarch64__)
crypto_int64 crypto_int64_r, crypto_int64_s;
__asm__ ("cmp %2,%3\n csel %0,%2,%3,lt\n csel %1,%3,%2,lt" : "=&r"(crypto_int64_r), "=r"(crypto_int64_s) : "r"(crypto_int64_x), "r"(crypto_int64_y) : "cc");
*crypto_int64_p = crypto_int64_r;
*crypto_int64_q = crypto_int64_s;
#else
crypto_int64 crypto_int64_r = crypto_int64_y ^ crypto_int64_x;
crypto_int64 crypto_int64_z = crypto_int64_y - crypto_int64_x;
crypto_int64_z ^= crypto_int64_r & (crypto_int64_z ^ crypto_int64_y);
crypto_int64_z = crypto_int64_negative_mask(crypto_int64_z);
crypto_int64_z &= crypto_int64_r;
crypto_int64_x ^= crypto_int64_z;
crypto_int64_y ^= crypto_int64_z;
*crypto_int64_p = crypto_int64_x;
*crypto_int64_q = crypto_int64_y;
#endif
}
__attribute__((unused))
static inline
crypto_int64 crypto_int64_smaller_mask(crypto_int64 crypto_int64_x,crypto_int64 crypto_int64_y) {
#if defined(__GNUC__) && defined(__x86_64__)
crypto_int64 crypto_int64_q,crypto_int64_z;
__asm__ ("xorq %0,%0\n movq $-1,%1\n cmpq %3,%2\n cmovlq %1,%0" : "=&r"(crypto_int64_z), "=&r"(crypto_int64_q) : "r"(crypto_int64_x), "r"(crypto_int64_y) : "cc");
return crypto_int64_z;
#elif defined(__GNUC__) && defined(__aarch64__)
crypto_int64 crypto_int64_z;
__asm__ ("cmp %1,%2\n csetm %0,lt" : "=r"(crypto_int64_z) : "r"(crypto_int64_x), "r"(crypto_int64_y) : "cc");
return crypto_int64_z;
#else
crypto_int64 crypto_int64_r = crypto_int64_x ^ crypto_int64_y;
crypto_int64 crypto_int64_z = crypto_int64_x - crypto_int64_y;
crypto_int64_z ^= crypto_int64_r & (crypto_int64_z ^ crypto_int64_x);
return crypto_int64_negative_mask(crypto_int64_z);
#endif
}
__attribute__((unused))
static inline
crypto_int64 crypto_int64_smaller_01(crypto_int64 crypto_int64_x,crypto_int64 crypto_int64_y) {
#if defined(__GNUC__) && defined(__x86_64__)
crypto_int64 crypto_int64_q,crypto_int64_z;
__asm__ ("xorq %0,%0\n movq $1,%1\n cmpq %3,%2\n cmovlq %1,%0" : "=&r"(crypto_int64_z), "=&r"(crypto_int64_q) : "r"(crypto_int64_x), "r"(crypto_int64_y) : "cc");
return crypto_int64_z;
#elif defined(__GNUC__) && defined(__aarch64__)
crypto_int64 crypto_int64_z;
__asm__ ("cmp %1,%2\n cset %0,lt" : "=r"(crypto_int64_z) : "r"(crypto_int64_x), "r"(crypto_int64_y) : "cc");
return crypto_int64_z;
#else
crypto_int64 crypto_int64_r = crypto_int64_x ^ crypto_int64_y;
crypto_int64 crypto_int64_z = crypto_int64_x - crypto_int64_y;
crypto_int64_z ^= crypto_int64_r & (crypto_int64_z ^ crypto_int64_x);
return crypto_int64_unsigned_topbit_01(crypto_int64_z);
#endif
}
__attribute__((unused))
static inline
crypto_int64 crypto_int64_leq_mask(crypto_int64 crypto_int64_x,crypto_int64 crypto_int64_y) {
#if defined(__GNUC__) && defined(__x86_64__)
crypto_int64 crypto_int64_q,crypto_int64_z;
__asm__ ("xorq %0,%0\n movq $-1,%1\n cmpq %3,%2\n cmovleq %1,%0" : "=&r"(crypto_int64_z), "=&r"(crypto_int64_q) : "r"(crypto_int64_x), "r"(crypto_int64_y) : "cc");
return crypto_int64_z;
#elif defined(__GNUC__) && defined(__aarch64__)
crypto_int64 crypto_int64_z;
__asm__ ("cmp %1,%2\n csetm %0,le" : "=r"(crypto_int64_z) : "r"(crypto_int64_x), "r"(crypto_int64_y) : "cc");
return crypto_int64_z;
#else
return ~crypto_int64_smaller_mask(crypto_int64_y,crypto_int64_x);
#endif
}
__attribute__((unused))
static inline
crypto_int64 crypto_int64_leq_01(crypto_int64 crypto_int64_x,crypto_int64 crypto_int64_y) {
#if defined(__GNUC__) && defined(__x86_64__)
crypto_int64 crypto_int64_q,crypto_int64_z;
__asm__ ("xorq %0,%0\n movq $1,%1\n cmpq %3,%2\n cmovleq %1,%0" : "=&r"(crypto_int64_z), "=&r"(crypto_int64_q) : "r"(crypto_int64_x), "r"(crypto_int64_y) : "cc");
return crypto_int64_z;
#elif defined(__GNUC__) && defined(__aarch64__)
crypto_int64 crypto_int64_z;
__asm__ ("cmp %1,%2\n cset %0,le" : "=r"(crypto_int64_z) : "r"(crypto_int64_x), "r"(crypto_int64_y) : "cc");
return crypto_int64_z;
#else
return 1-crypto_int64_smaller_01(crypto_int64_y,crypto_int64_x);
#endif
}
__attribute__((unused))
static inline
int crypto_int64_ones_num(crypto_int64 crypto_int64_x) {
crypto_int64_unsigned crypto_int64_y = crypto_int64_x;
const crypto_int64 C0 = 0x5555555555555555;
const crypto_int64 C1 = 0x3333333333333333;
const crypto_int64 C2 = 0x0f0f0f0f0f0f0f0f;
crypto_int64_y -= ((crypto_int64_y >> 1) & C0);
crypto_int64_y = (crypto_int64_y & C1) + ((crypto_int64_y >> 2) & C1);
crypto_int64_y = (crypto_int64_y + (crypto_int64_y >> 4)) & C2;
crypto_int64_y += crypto_int64_y >> 8;
crypto_int64_y += crypto_int64_y >> 16;
crypto_int64_y = (crypto_int64_y + (crypto_int64_y >> 32)) & 0xff;
return crypto_int64_y;
}
__attribute__((unused))
static inline
int crypto_int64_bottomzeros_num(crypto_int64 crypto_int64_x) {
#if defined(__GNUC__) && defined(__x86_64__)
crypto_int64 fallback = 64;
__asm__ ("bsfq %0,%0\n cmoveq %1,%0" : "+&r"(crypto_int64_x) : "r"(fallback) : "cc");
return crypto_int64_x;
#elif defined(__GNUC__) && defined(__aarch64__)
int64_t crypto_int64_y;
__asm__ ("rbit %0,%1\n clz %0,%0" : "=r"(crypto_int64_y) : "r"(crypto_int64_x) : );
return crypto_int64_y;
#else
crypto_int64 crypto_int64_y = crypto_int64_x ^ (crypto_int64_x-1);
crypto_int64_y = ((crypto_int64) crypto_int64_y) >> 1;
crypto_int64_y &= ~(crypto_int64_x & (((crypto_int64) 1) << (64-1)));
return crypto_int64_ones_num(crypto_int64_y);
#endif
}
#endif
/* from supercop-20240808/crypto_sort/int32/portable4/sort.c */
#define int32_MINMAX(a,b) crypto_int32_minmax(&a,&b)
static void crypto_sort_int32(void *array,long long n)
{
long long top,p,q,r,i,j;
int32 *x = array;
if (n < 2) return;
top = 1;
while (top < n - top) top += top;
for (p = top;p >= 1;p >>= 1) {
i = 0;
while (i + 2 * p <= n) {
for (j = i;j < i + p;++j)
int32_MINMAX(x[j],x[j+p]);
i += 2 * p;
}
for (j = i;j < n - p;++j)
int32_MINMAX(x[j],x[j+p]);
i = 0;
j = 0;
for (q = top;q > p;q >>= 1) {
if (j != i) for (;;) {
if (j == n - q) goto done;
int32 a = x[j + p];
for (r = q;r > p;r >>= 1)
int32_MINMAX(a,x[j + r]);
x[j + p] = a;
++j;
if (j == i + p) {
i += 2 * p;
break;
}
}
while (i + p <= n - q) {
for (j = i;j < i + p;++j) {
int32 a = x[j + p];
for (r = q;r > p;r >>= 1)
int32_MINMAX(a,x[j+r]);
x[j + p] = a;
}
i += 2 * p;
}
/* now i + p > n - q */
j = i;
while (j < n - q) {
int32 a = x[j + p];
for (r = q;r > p;r >>= 1)
int32_MINMAX(a,x[j+r]);
x[j + p] = a;
++j;
}
done: ;
}
}
}
/* from supercop-20240808/crypto_sort/uint32/useint32/sort.c */
/* can save time by vectorizing xor loops */
/* can save time by integrating xor loops with int32_sort */
static void crypto_sort_uint32(void *array,long long n)
{
crypto_uint32 *x = array;
long long j;
for (j = 0;j < n;++j) x[j] ^= 0x80000000;
crypto_sort_int32(array,n);
for (j = 0;j < n;++j) x[j] ^= 0x80000000;
}
/* from supercop-20240808/crypto_kem/sntrup761/compact/kem.c */
// 20240806 djb: some automated conversion to cryptoint
#define p 761
#define q 4591
#define w 286
#define q12 ((q - 1) / 2)
typedef int8_t small;
typedef int16_t Fq;
#define Hash_bytes 32
#define Small_bytes ((p + 3) / 4)
typedef small Inputs[p];
#define SecretKeys_bytes (2 * Small_bytes)
#define Confirm_bytes 32
static small F3_freeze(int16_t x) { return x - 3 * ((10923 * x + 16384) >> 15); }
static Fq Fq_freeze(int32_t x) {
const int32_t q16 = (0x10000 + q / 2) / q;
const int32_t q20 = (0x100000 + q / 2) / q;
const int32_t q28 = (0x10000000 + q / 2) / q;
x -= q * ((q16 * x) >> 16);
x -= q * ((q20 * x) >> 20);
return x - q * ((q28 * x + 0x8000000) >> 28);
}
static int Weightw_mask(small *r) {
int i, weight = 0;
for (i = 0; i < p; ++i) weight += crypto_int64_bottombit_01(r[i]);
return crypto_int16_nonzero_mask(weight - w);
}
static void uint32_divmod_uint14(uint32_t *Q, uint16_t *r, uint32_t x, uint16_t m) {
uint32_t qpart, mask, v = 0x80000000 / m;
qpart = (x * (uint64_t)v) >> 31;
x -= qpart * m;
*Q = qpart;
qpart = (x * (uint64_t)v) >> 31;
x -= qpart * m;
*Q += qpart;
x -= m;
*Q += 1;
mask = crypto_int32_negative_mask(x);
x += mask & (uint32_t)m;
*Q += mask;
*r = x;
}
static uint16_t uint32_mod_uint14(uint32_t x, uint16_t m) {
uint32_t Q;
uint16_t r;
uint32_divmod_uint14(&Q, &r, x, m);
return r;
}
static void Encode(unsigned char *out, const uint16_t *R, const uint16_t *M, long long len) {
if (len == 1) {
uint16_t r = R[0], m = M[0];
while (m > 1) {
*out++ = r;
r >>= 8;
m = (m + 255) >> 8;
}
}
if (len > 1) {
uint16_t R2[(len + 1) / 2], M2[(len + 1) / 2];
long long i;
for (i = 0; i < len - 1; i += 2) {
uint32_t m0 = M[i];
uint32_t r = R[i] + R[i + 1] * m0;
uint32_t m = M[i + 1] * m0;
while (m >= 16384) {
*out++ = r;
r >>= 8;
m = (m + 255) >> 8;
}
R2[i / 2] = r;
M2[i / 2] = m;
}
if (i < len) {
R2[i / 2] = R[i];
M2[i / 2] = M[i];
}
Encode(out, R2, M2, (len + 1) / 2);
}
}
static void Decode(uint16_t *out, const unsigned char *S, const uint16_t *M, long long len) {
if (len == 1) {
if (M[0] == 1)
*out = 0;
else if (M[0] <= 256)
*out = uint32_mod_uint14(S[0], M[0]);
else
*out = uint32_mod_uint14(S[0] + (((uint16_t)S[1]) << 8), M[0]);
}
if (len > 1) {
uint16_t R2[(len + 1) / 2], M2[(len + 1) / 2], bottomr[len / 2];
uint32_t bottomt[len / 2];
long long i;
for (i = 0; i < len - 1; i += 2) {
uint32_t m = M[i] * (uint32_t)M[i + 1];
if (m > 256 * 16383) {
bottomt[i / 2] = 256 * 256;
bottomr[i / 2] = S[0] + 256 * S[1];
S += 2;
M2[i / 2] = (((m + 255) >> 8) + 255) >> 8;
} else if (m >= 16384) {
bottomt[i / 2] = 256;
bottomr[i / 2] = S[0];
S += 1;
M2[i / 2] = (m + 255) >> 8;
} else {
bottomt[i / 2] = 1;
bottomr[i / 2] = 0;
M2[i / 2] = m;
}
}
if (i < len) M2[i / 2] = M[i];
Decode(R2, S, M2, (len + 1) / 2);
for (i = 0; i < len - 1; i += 2) {
uint32_t r1, r = bottomr[i / 2];
uint16_t r0;
r += bottomt[i / 2] * R2[i / 2];
uint32_divmod_uint14(&r1, &r0, r, M[i]);
r1 = uint32_mod_uint14(r1, M[i + 1]);
*out++ = r0;
*out++ = r1;
}
if (i < len) *out++ = R2[i / 2];
}
}
static void R3_fromRq(small *out, const Fq *r) {
int i;
for (i = 0; i < p; ++i) out[i] = F3_freeze(r[i]);
}
static void R3_mult(small *h, const small *f, const small *g) {
int16_t fg[p + p - 1];
int i, j;
for (i = 0; i < p + p - 1; ++i) fg[i] = 0;
for (i = 0; i < p; ++i)
for (j = 0; j < p; ++j) fg[i + j] += f[i] * (int16_t)g[j];
for (i = p; i < p + p - 1; ++i) fg[i - p] += fg[i];
for (i = p; i < p + p - 1; ++i) fg[i - p + 1] += fg[i];
for (i = 0; i < p; ++i) h[i] = F3_freeze(fg[i]);
}
static int R3_recip(small *out, const small *in) {
small f[p + 1], g[p + 1], v[p + 1], r[p + 1];
int sign, swap, t, i, loop, delta = 1;
for (i = 0; i < p + 1; ++i) v[i] = 0;
for (i = 0; i < p + 1; ++i) r[i] = 0;
r[0] = 1;
for (i = 0; i < p; ++i) f[i] = 0;
f[0] = 1;
f[p - 1] = f[p] = -1;
for (i = 0; i < p; ++i) g[p - 1 - i] = in[i];
g[p] = 0;
for (loop = 0; loop < 2 * p - 1; ++loop) {
for (i = p; i > 0; --i) v[i] = v[i - 1];
v[0] = 0;
sign = -g[0] * f[0];
swap = crypto_int16_negative_mask(-delta) & crypto_int16_nonzero_mask(g[0]);
delta ^= swap & (delta ^ -delta);
delta += 1;
for (i = 0; i < p + 1; ++i) {
t = swap & (f[i] ^ g[i]);
f[i] ^= t;
g[i] ^= t;
t = swap & (v[i] ^ r[i]);
v[i] ^= t;
r[i] ^= t;
}
for (i = 0; i < p + 1; ++i) g[i] = F3_freeze(g[i] + sign * f[i]);
for (i = 0; i < p + 1; ++i) r[i] = F3_freeze(r[i] + sign * v[i]);
for (i = 0; i < p; ++i) g[i] = g[i + 1];
g[p] = 0;
}
sign = f[0];
for (i = 0; i < p; ++i) out[i] = sign * v[p - 1 - i];
return crypto_int16_nonzero_mask(delta);
}
static void Rq_mult_small(Fq *h, const Fq *f, const small *g) {
int32_t fg[p + p - 1];
int i, j;
for (i = 0; i < p + p - 1; ++i) fg[i] = 0;
for (i = 0; i < p; ++i)
for (j = 0; j < p; ++j) fg[i + j] += f[i] * (int32_t)g[j];
for (i = p; i < p + p - 1; ++i) fg[i - p] += fg[i];
for (i = p; i < p + p - 1; ++i) fg[i - p + 1] += fg[i];
for (i = 0; i < p; ++i) h[i] = Fq_freeze(fg[i]);
}
static void Rq_mult3(Fq *h, const Fq *f) {
int i;
for (i = 0; i < p; ++i) h[i] = Fq_freeze(3 * f[i]);
}
static Fq Fq_recip(Fq a1) {
int i = 1;
Fq ai = a1;
while (i < q - 2) {
ai = Fq_freeze(a1 * (int32_t)ai);
i += 1;
}
return ai;
}
static int Rq_recip3(Fq *out, const small *in) {
Fq f[p + 1], g[p + 1], v[p + 1], r[p + 1], scale;
int swap, t, i, loop, delta = 1;
int32_t f0, g0;
for (i = 0; i < p + 1; ++i) v[i] = 0;
for (i = 0; i < p + 1; ++i) r[i] = 0;
r[0] = Fq_recip(3);
for (i = 0; i < p; ++i) f[i] = 0;
f[0] = 1;
f[p - 1] = f[p] = -1;
for (i = 0; i < p; ++i) g[p - 1 - i] = in[i];
g[p] = 0;
for (loop = 0; loop < 2 * p - 1; ++loop) {
for (i = p; i > 0; --i) v[i] = v[i - 1];
v[0] = 0;
swap = crypto_int16_negative_mask(-delta) & crypto_int16_nonzero_mask(g[0]);
delta ^= swap & (delta ^ -delta);
delta += 1;
for (i = 0; i < p + 1; ++i) {
t = swap & (f[i] ^ g[i]);
f[i] ^= t;
g[i] ^= t;
t = swap & (v[i] ^ r[i]);
v[i] ^= t;
r[i] ^= t;
}
f0 = f[0];
g0 = g[0];
for (i = 0; i < p + 1; ++i) g[i] = Fq_freeze(f0 * g[i] - g0 * f[i]);
for (i = 0; i < p + 1; ++i) r[i] = Fq_freeze(f0 * r[i] - g0 * v[i]);
for (i = 0; i < p; ++i) g[i] = g[i + 1];
g[p] = 0;
}
scale = Fq_recip(f[0]);
for (i = 0; i < p; ++i) out[i] = Fq_freeze(scale * (int32_t)v[p - 1 - i]);
return crypto_int16_nonzero_mask(delta);
}
static void Round(Fq *out, const Fq *a) {
int i;
for (i = 0; i < p; ++i) out[i] = a[i] - F3_freeze(a[i]);
}
static void Short_fromlist(small *out, const uint32_t *in) {
uint32_t L[p];
int i;
for (i = 0; i < w; ++i) L[i] = in[i] & (uint32_t)-2;
for (i = w; i < p; ++i) L[i] = (in[i] & (uint32_t)-3) | 1;
crypto_sort_uint32(L, p);
for (i = 0; i < p; ++i) out[i] = (L[i] & 3) - 1;
}
static void Hash_prefix(unsigned char *out, int b, const unsigned char *in, int inlen) {
unsigned char x[inlen + 1], h[64];
int i;
x[0] = b;
for (i = 0; i < inlen; ++i) x[i + 1] = in[i];
crypto_hash_sha512(h, x, inlen + 1);
for (i = 0; i < 32; ++i) out[i] = h[i];
}
static uint32_t urandom32(void) {
unsigned char c[4];
uint32_t result = 0;
int i;
randombytes(c, 4);
for (i = 0; i < 4; ++i) result += ((uint32_t)c[i]) << (8 * i);
return result;
}
static void Short_random(small *out) {
uint32_t L[p];
int i;
for (i = 0; i < p; ++i) L[i] = urandom32();
Short_fromlist(out, L);
}
static void Small_random(small *out) {
int i;
for (i = 0; i < p; ++i) out[i] = (((urandom32() & 0x3fffffff) * 3) >> 30) - 1;
}
static void KeyGen(Fq *h, small *f, small *ginv) {
small g[p];
Fq finv[p];
for (;;) {
int result;
Small_random(g);
result = R3_recip(ginv, g);
crypto_declassify(&result, sizeof result);
if (result == 0) break;
}
Short_random(f);
Rq_recip3(finv, f);
Rq_mult_small(h, finv, g);
}
static void Encrypt(Fq *c, const small *r, const Fq *h) {
Fq hr[p];
Rq_mult_small(hr, h, r);
Round(c, hr);
}
static void Decrypt(small *r, const Fq *c, const small *f, const small *ginv) {
Fq cf[p], cf3[p];
small e[p], ev[p];
int mask, i;
Rq_mult_small(cf, c, f);
Rq_mult3(cf3, cf);
R3_fromRq(e, cf3);
R3_mult(ev, e, ginv);
mask = Weightw_mask(ev);
for (i = 0; i < w; ++i) r[i] = ((ev[i] ^ 1) & ~mask) ^ 1;
for (i = w; i < p; ++i) r[i] = ev[i] & ~mask;
}
static void Small_encode(unsigned char *s, const small *f) {
int i, j;
for (i = 0; i < p / 4; ++i) {
small x = 0;
for (j = 0;j < 4;++j) x += (*f++ + 1) << (2 * j);
*s++ = x;
}
*s = *f++ + 1;
}
static void Small_decode(small *f, const unsigned char *s) {
int i, j;
for (i = 0; i < p / 4; ++i) {
unsigned char x = *s++;
for (j = 0;j < 4;++j) *f++ = ((small)((x >> (2 * j)) & 3)) - 1;
}
*f++ = ((small)(*s & 3)) - 1;
}
static void Rq_encode(unsigned char *s, const Fq *r) {
uint16_t R[p], M[p];
int i;
for (i = 0; i < p; ++i) R[i] = r[i] + q12;
for (i = 0; i < p; ++i) M[i] = q;
Encode(s, R, M, p);
}
static void Rq_decode(Fq *r, const unsigned char *s) {
uint16_t R[p], M[p];
int i;
for (i = 0; i < p; ++i) M[i] = q;
Decode(R, s, M, p);
for (i = 0; i < p; ++i) r[i] = ((Fq)R[i]) - q12;
}
static void Rounded_encode(unsigned char *s, const Fq *r) {
uint16_t R[p], M[p];
int i;
for (i = 0; i < p; ++i) R[i] = ((r[i] + q12) * 10923) >> 15;
for (i = 0; i < p; ++i) M[i] = (q + 2) / 3;
Encode(s, R, M, p);
}
static void Rounded_decode(Fq *r, const unsigned char *s) {
uint16_t R[p], M[p];
int i;
for (i = 0; i < p; ++i) M[i] = (q + 2) / 3;
Decode(R, s, M, p);
for (i = 0; i < p; ++i) r[i] = R[i] * 3 - q12;
}
static void ZKeyGen(unsigned char *pk, unsigned char *sk) {
Fq h[p];
small f[p], v[p];
KeyGen(h, f, v);
Rq_encode(pk, h);
Small_encode(sk, f);
Small_encode(sk + Small_bytes, v);
}
static void ZEncrypt(unsigned char *C, const Inputs r, const unsigned char *pk) {
Fq h[p], c[p];
Rq_decode(h, pk);
Encrypt(c, r, h);
Rounded_encode(C, c);
}
static void ZDecrypt(Inputs r, const unsigned char *C, const unsigned char *sk) {
small f[p], v[p];
Fq c[p];
Small_decode(f, sk);
Small_decode(v, sk + Small_bytes);
Rounded_decode(c, C);
Decrypt(r, c, f, v);
}
static void HashConfirm(unsigned char *h, const unsigned char *r, const unsigned char *cache) {
unsigned char x[Hash_bytes * 2];
int i;
Hash_prefix(x, 3, r, Small_bytes);
for (i = 0; i < Hash_bytes; ++i) x[Hash_bytes + i] = cache[i];
Hash_prefix(h, 2, x, sizeof x);
}
static void HashSession(unsigned char *k, int b, const unsigned char *y, const unsigned char *z) {
unsigned char x[Hash_bytes + crypto_kem_sntrup761_CIPHERTEXTBYTES];
int i;
Hash_prefix(x, 3, y, Small_bytes);
for (i = 0; i < crypto_kem_sntrup761_CIPHERTEXTBYTES; ++i) x[Hash_bytes + i] = z[i];
Hash_prefix(k, b, x, sizeof x);
}
int crypto_kem_sntrup761_keypair(unsigned char *pk, unsigned char *sk) {
int i;
ZKeyGen(pk, sk);
sk += SecretKeys_bytes;
for (i = 0; i < crypto_kem_sntrup761_PUBLICKEYBYTES; ++i) *sk++ = pk[i];
randombytes(sk, Small_bytes);
Hash_prefix(sk + Small_bytes, 4, pk, crypto_kem_sntrup761_PUBLICKEYBYTES);
return 0;
}
static void Hide(unsigned char *c, unsigned char *r_enc, const Inputs r, const unsigned char *pk, const unsigned char *cache) {
Small_encode(r_enc, r);
ZEncrypt(c, r, pk);
HashConfirm(c + crypto_kem_sntrup761_CIPHERTEXTBYTES - Confirm_bytes, r_enc, cache);
}
int crypto_kem_sntrup761_enc(unsigned char *c, unsigned char *k, const unsigned char *pk) {
Inputs r;
unsigned char r_enc[Small_bytes], cache[Hash_bytes];
Hash_prefix(cache, 4, pk, crypto_kem_sntrup761_PUBLICKEYBYTES);
Short_random(r);
Hide(c, r_enc, r, pk, cache);
HashSession(k, 1, r_enc, c);
return 0;
}
static int Ciphertexts_diff_mask(const unsigned char *c, const unsigned char *c2) {
uint16_t differentbits = 0;
int len = crypto_kem_sntrup761_CIPHERTEXTBYTES;
while (len-- > 0) differentbits |= (*c++) ^ (*c2++);
return (crypto_int64_bitmod_01((differentbits - 1),8)) - 1;
}
int crypto_kem_sntrup761_dec(unsigned char *k, const unsigned char *c, const unsigned char *sk) {
const unsigned char *pk = sk + SecretKeys_bytes;
const unsigned char *rho = pk + crypto_kem_sntrup761_PUBLICKEYBYTES;
const unsigned char *cache = rho + Small_bytes;
Inputs r;
unsigned char r_enc[Small_bytes], cnew[crypto_kem_sntrup761_CIPHERTEXTBYTES];
int mask, i;
ZDecrypt(r, c, sk);
Hide(cnew, r_enc, r, pk, cache);
mask = Ciphertexts_diff_mask(c, cnew);
for (i = 0; i < Small_bytes; ++i) r_enc[i] ^= mask & (r_enc[i] ^ rho[i]);
HashSession(k, 1 + mask, r_enc, c);
return 0;
}
#endif /* USE_SNTRUP761X25519 */