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mbedtls/3rdparty/everest/library/kremlib/fstar_uint128.c
Christoph M. Wintersteiger bee486146e ECDH: Add Everest Curve25519 to 3rdparty/everest 
These files are automatically generated by the Everest toolchain from F*
files. They do not respect the mbedTLS code style guidelines as manual
modification would invalidate verification guarantees. The files in
3rdparty/everest/include/kremli{n,b} are a customized (minimzed) version of the
support headers expected by the code extracted using KreMLin.
2019-08-19 13:19:38 +01:00

217 lines
5.5 KiB
C
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/* Copyright (c) INRIA and Microsoft Corporation. All rights reserved.
Licensed under the Apache 2.0 License. */
/******************************************************************************/
/* Machine integers (128-bit arithmetic) */
/******************************************************************************/
/* This header makes KreMLin-generated C code work with:
* - the default setting where we assume the target compiler defines __int128
* - the setting where we use FStar.UInt128's implementation instead; in that
* case, generated C files must be compiled with -DKRML_VERIFIED_UINT128
* - a refinement of the case above, wherein all structures are passed by
* reference, a.k.a. "-fnostruct-passing", meaning that the KreMLin-generated
* must be compiled with -DKRML_NOSTRUCT_PASSING
* Note: no MSVC support in this file.
*/
#include "FStar_UInt128.h"
#include "kremlin/c_endianness.h"
#include "FStar_UInt64_FStar_UInt32_FStar_UInt16_FStar_UInt8.h"
#if !defined(KRML_VERIFIED_UINT128) && !defined(_MSC_VER)
/* GCC + using native unsigned __int128 support */
uint128_t load128_le(uint8_t *b) {
uint128_t l = (uint128_t)load64_le(b);
uint128_t h = (uint128_t)load64_le(b + 8);
return (h << 64 | l);
}
void store128_le(uint8_t *b, uint128_t n) {
store64_le(b, (uint64_t)n);
store64_le(b + 8, (uint64_t)(n >> 64));
}
uint128_t load128_be(uint8_t *b) {
uint128_t h = (uint128_t)load64_be(b);
uint128_t l = (uint128_t)load64_be(b + 8);
return (h << 64 | l);
}
void store128_be(uint8_t *b, uint128_t n) {
store64_be(b, (uint64_t)(n >> 64));
store64_be(b + 8, (uint64_t)n);
}
uint128_t FStar_UInt128_add(uint128_t x, uint128_t y) {
return x + y;
}
uint128_t FStar_UInt128_mul(uint128_t x, uint128_t y) {
return x * y;
}
uint128_t FStar_UInt128_add_mod(uint128_t x, uint128_t y) {
return x + y;
}
uint128_t FStar_UInt128_sub(uint128_t x, uint128_t y) {
return x - y;
}
uint128_t FStar_UInt128_sub_mod(uint128_t x, uint128_t y) {
return x - y;
}
uint128_t FStar_UInt128_logand(uint128_t x, uint128_t y) {
return x & y;
}
uint128_t FStar_UInt128_logor(uint128_t x, uint128_t y) {
return x | y;
}
uint128_t FStar_UInt128_logxor(uint128_t x, uint128_t y) {
return x ^ y;
}
uint128_t FStar_UInt128_lognot(uint128_t x) {
return ~x;
}
uint128_t FStar_UInt128_shift_left(uint128_t x, uint32_t y) {
return x << y;
}
uint128_t FStar_UInt128_shift_right(uint128_t x, uint32_t y) {
return x >> y;
}
uint128_t FStar_UInt128_uint64_to_uint128(uint64_t x) {
return (uint128_t)x;
}
uint64_t FStar_UInt128_uint128_to_uint64(uint128_t x) {
return (uint64_t)x;
}
uint128_t FStar_UInt128_mul_wide(uint64_t x, uint64_t y) {
return ((uint128_t) x) * y;
}
uint128_t FStar_UInt128_eq_mask(uint128_t x, uint128_t y) {
uint64_t mask =
FStar_UInt64_eq_mask((uint64_t)(x >> 64), (uint64_t)(y >> 64)) &
FStar_UInt64_eq_mask(x, y);
return ((uint128_t)mask) << 64 | mask;
}
uint128_t FStar_UInt128_gte_mask(uint128_t x, uint128_t y) {
uint64_t mask =
(FStar_UInt64_gte_mask(x >> 64, y >> 64) &
~(FStar_UInt64_eq_mask(x >> 64, y >> 64))) |
(FStar_UInt64_eq_mask(x >> 64, y >> 64) & FStar_UInt64_gte_mask(x, y));
return ((uint128_t)mask) << 64 | mask;
}
uint128_t FStar_Int_Cast_Full_uint64_to_uint128(uint64_t x) {
return x;
}
uint64_t FStar_Int_Cast_Full_uint128_to_uint64(uint128_t x) {
return x;
}
#elif !defined(_MSC_VER) && defined(KRML_VERIFIED_UINT128)
/* Verified uint128 implementation. */
/* Access 64-bit fields within the int128. */
#define HIGH64_OF(x) ((x)->high)
#define LOW64_OF(x) ((x)->low)
typedef FStar_UInt128_uint128 FStar_UInt128_t_, uint128_t;
/* A series of definitions written using pointers. */
void load128_le_(uint8_t *b, uint128_t *r) {
LOW64_OF(r) = load64_le(b);
HIGH64_OF(r) = load64_le(b + 8);
}
void store128_le_(uint8_t *b, uint128_t *n) {
store64_le(b, LOW64_OF(n));
store64_le(b + 8, HIGH64_OF(n));
}
void load128_be_(uint8_t *b, uint128_t *r) {
HIGH64_OF(r) = load64_be(b);
LOW64_OF(r) = load64_be(b + 8);
}
void store128_be_(uint8_t *b, uint128_t *n) {
store64_be(b, HIGH64_OF(n));
store64_be(b + 8, LOW64_OF(n));
}
void
FStar_Int_Cast_Full_uint64_to_uint128_(uint64_t x, uint128_t *dst) {
/* C89 */
LOW64_OF(dst) = x;
HIGH64_OF(dst) = 0;
}
uint64_t FStar_Int_Cast_Full_uint128_to_uint64_(uint128_t *x) {
return LOW64_OF(x);
}
# ifndef KRML_NOSTRUCT_PASSING
uint128_t load128_le(uint8_t *b) {
uint128_t r;
load128_le_(b, &r);
return r;
}
void store128_le(uint8_t *b, uint128_t n) {
store128_le_(b, &n);
}
uint128_t load128_be(uint8_t *b) {
uint128_t r;
load128_be_(b, &r);
return r;
}
void store128_be(uint8_t *b, uint128_t n) {
store128_be_(b, &n);
}
uint128_t FStar_Int_Cast_Full_uint64_to_uint128(uint64_t x) {
uint128_t dst;
FStar_Int_Cast_Full_uint64_to_uint128_(x, &dst);
return dst;
}
uint64_t FStar_Int_Cast_Full_uint128_to_uint64(uint128_t x) {
return FStar_Int_Cast_Full_uint128_to_uint64_(&x);
}
# else /* !defined(KRML_STRUCT_PASSING) */
# define print128 print128_
# define load128_le load128_le_
# define store128_le store128_le_
# define load128_be load128_be_
# define store128_be store128_be_
# define FStar_Int_Cast_Full_uint128_to_uint64 \
FStar_Int_Cast_Full_uint128_to_uint64_
# define FStar_Int_Cast_Full_uint64_to_uint128 \
FStar_Int_Cast_Full_uint64_to_uint128_
# endif /* KRML_STRUCT_PASSING */
#endif
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