Nagram/TMessagesProj/jni/boringssl/crypto/chacha/chacha_vec.c

/* Copyright (c) 2014, Google Inc.
 *
 * Permission to use, copy, modify, and/or distribute this software for any
 * purpose with or without fee is hereby granted, provided that the above
 * copyright notice and this permission notice appear in all copies.
 *
 * THE SOFTWARE IS PROVIDED "AS IS" AND THE AUTHOR DISCLAIMS ALL WARRANTIES
 * WITH REGARD TO THIS SOFTWARE INCLUDING ALL IMPLIED WARRANTIES OF
 * MERCHANTABILITY AND FITNESS. IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY
 * SPECIAL, DIRECT, INDIRECT, OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES
 * WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR PROFITS, WHETHER IN AN ACTION
 * OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT OF OR IN
 * CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE. */

/* ====================================================================
 *
 * When updating this file, also update chacha_vec_arm.S
 *
 * ==================================================================== */


/* This implementation is by Ted Krovetz and was submitted to SUPERCOP and
 * marked as public domain. It was been altered to allow for non-aligned inputs
 * and to allow the block counter to be passed in specifically. */

#include <openssl/chacha.h>

#if defined(ASM_GEN) ||          \
    !defined(OPENSSL_WINDOWS) && \
        (defined(OPENSSL_X86_64) || defined(OPENSSL_X86)) && defined(__SSE2__)

#define CHACHA_RNDS 20 /* 8 (high speed), 20 (conservative), 12 (middle) */

/* Architecture-neutral way to specify 16-byte vector of ints              */
typedef unsigned vec __attribute__((vector_size(16)));

/* This implementation is designed for Neon, SSE and AltiVec machines. The
 * following specify how to do certain vector operations efficiently on
 * each architecture, using intrinsics.
 * This implementation supports parallel processing of multiple blocks,
 * including potentially using general-purpose registers. */
#if __ARM_NEON__
#include <string.h>
#include <arm_neon.h>
#define GPR_TOO 1
#define VBPI 2
#define ONE (vec) vsetq_lane_u32(1, vdupq_n_u32(0), 0)
#define LOAD_ALIGNED(m) (vec)(*((vec *)(m)))
#define LOAD(m) ({ \
    memcpy(alignment_buffer, m, 16); \
    LOAD_ALIGNED(alignment_buffer); \
  })
#define STORE(m, r) ({ \
    (*((vec *)(alignment_buffer))) = (r); \
    memcpy(m, alignment_buffer, 16); \
  })
#define ROTV1(x) (vec) vextq_u32((uint32x4_t)x, (uint32x4_t)x, 1)
#define ROTV2(x) (vec) vextq_u32((uint32x4_t)x, (uint32x4_t)x, 2)
#define ROTV3(x) (vec) vextq_u32((uint32x4_t)x, (uint32x4_t)x, 3)
#define ROTW16(x) (vec) vrev32q_u16((uint16x8_t)x)
#if __clang__
#define ROTW7(x) (x << ((vec) {7, 7, 7, 7})) ^ (x >> ((vec) {25, 25, 25, 25}))
#define ROTW8(x) (x << ((vec) {8, 8, 8, 8})) ^ (x >> ((vec) {24, 24, 24, 24}))
#define ROTW12(x) \
  (x << ((vec) {12, 12, 12, 12})) ^ (x >> ((vec) {20, 20, 20, 20}))
#else
#define ROTW7(x) \
  (vec) vsriq_n_u32(vshlq_n_u32((uint32x4_t)x, 7), (uint32x4_t)x, 25)
#define ROTW8(x) \
  (vec) vsriq_n_u32(vshlq_n_u32((uint32x4_t)x, 8), (uint32x4_t)x, 24)
#define ROTW12(x) \
  (vec) vsriq_n_u32(vshlq_n_u32((uint32x4_t)x, 12), (uint32x4_t)x, 20)
#endif
#elif __SSE2__
#include <emmintrin.h>
#define GPR_TOO 0
#if __clang__
#define VBPI 4
#else
#define VBPI 3
#endif
#define ONE (vec) _mm_set_epi32(0, 0, 0, 1)
#define LOAD(m) (vec) _mm_loadu_si128((__m128i *)(m))
#define LOAD_ALIGNED(m) (vec) _mm_load_si128((__m128i *)(m))
#define STORE(m, r) _mm_storeu_si128((__m128i *)(m), (__m128i)(r))
#define ROTV1(x) (vec) _mm_shuffle_epi32((__m128i)x, _MM_SHUFFLE(0, 3, 2, 1))
#define ROTV2(x) (vec) _mm_shuffle_epi32((__m128i)x, _MM_SHUFFLE(1, 0, 3, 2))
#define ROTV3(x) (vec) _mm_shuffle_epi32((__m128i)x, _MM_SHUFFLE(2, 1, 0, 3))
#define ROTW7(x) \
  (vec)(_mm_slli_epi32((__m128i)x, 7) ^ _mm_srli_epi32((__m128i)x, 25))
#define ROTW12(x) \
  (vec)(_mm_slli_epi32((__m128i)x, 12) ^ _mm_srli_epi32((__m128i)x, 20))
#if __SSSE3__
#include <tmmintrin.h>
#define ROTW8(x)                                                            \
  (vec) _mm_shuffle_epi8((__m128i)x, _mm_set_epi8(14, 13, 12, 15, 10, 9, 8, \
                                                  11, 6, 5, 4, 7, 2, 1, 0, 3))
#define ROTW16(x)                                                           \
  (vec) _mm_shuffle_epi8((__m128i)x, _mm_set_epi8(13, 12, 15, 14, 9, 8, 11, \
                                                  10, 5, 4, 7, 6, 1, 0, 3, 2))
#else
#define ROTW8(x) \
  (vec)(_mm_slli_epi32((__m128i)x, 8) ^ _mm_srli_epi32((__m128i)x, 24))
#define ROTW16(x) \
  (vec)(_mm_slli_epi32((__m128i)x, 16) ^ _mm_srli_epi32((__m128i)x, 16))
#endif
#else
#error-- Implementation supports only machines with neon or SSE2
#endif

#ifndef REVV_BE
#define REVV_BE(x)  (x)
#endif

#ifndef REVW_BE
#define REVW_BE(x)  (x)
#endif

#define BPI      (VBPI + GPR_TOO)  /* Blocks computed per loop iteration   */

#define DQROUND_VECTORS(a,b,c,d)                \
    a += b; d ^= a; d = ROTW16(d);              \
    c += d; b ^= c; b = ROTW12(b);              \
    a += b; d ^= a; d = ROTW8(d);               \
    c += d; b ^= c; b = ROTW7(b);               \
    b = ROTV1(b); c = ROTV2(c);  d = ROTV3(d);  \
    a += b; d ^= a; d = ROTW16(d);              \
    c += d; b ^= c; b = ROTW12(b);              \
    a += b; d ^= a; d = ROTW8(d);               \
    c += d; b ^= c; b = ROTW7(b);               \
    b = ROTV3(b); c = ROTV2(c); d = ROTV1(d);

#define QROUND_WORDS(a,b,c,d) \
  a = a+b; d ^= a; d = d<<16 | d>>16; \
  c = c+d; b ^= c; b = b<<12 | b>>20; \
  a = a+b; d ^= a; d = d<< 8 | d>>24; \
  c = c+d; b ^= c; b = b<< 7 | b>>25;

#define WRITE_XOR(in, op, d, v0, v1, v2, v3)                   \
	STORE(op + d + 0, LOAD(in + d + 0) ^ REVV_BE(v0));      \
	STORE(op + d + 4, LOAD(in + d + 4) ^ REVV_BE(v1));      \
	STORE(op + d + 8, LOAD(in + d + 8) ^ REVV_BE(v2));      \
	STORE(op + d +12, LOAD(in + d +12) ^ REVV_BE(v3));

#if __ARM_NEON__
/* For ARM, we can't depend on NEON support, so this function is compiled with
 * a different name, along with the generic code, and can be enabled at
 * run-time. */
void CRYPTO_chacha_20_neon(
#else
void CRYPTO_chacha_20(
#endif
	uint8_t *out,
	const uint8_t *in,
	size_t inlen,
	const uint8_t key[32],
	const uint8_t nonce[8],
	size_t counter)
	{
	unsigned iters, i, *op=(unsigned *)out, *ip=(unsigned *)in, *kp;
#if defined(__ARM_NEON__)
	uint32_t np[2];
	uint8_t alignment_buffer[16] __attribute__((aligned(16)));
#endif
	vec s0, s1, s2, s3;
	__attribute__ ((aligned (16))) unsigned chacha_const[] =
		{0x61707865,0x3320646E,0x79622D32,0x6B206574};
	kp = (unsigned *)key;
#if defined(__ARM_NEON__)
	memcpy(np, nonce, 8);
#endif
	s0 = LOAD_ALIGNED(chacha_const);
	s1 = LOAD(&((vec*)kp)[0]);
	s2 = LOAD(&((vec*)kp)[1]);
	s3 = (vec){
		counter & 0xffffffff,
#if __ARM_NEON__ || defined(OPENSSL_X86)
		0,  /* can't right-shift 32 bits on a 32-bit system. */
#else
		counter >> 32,
#endif
		((uint32_t*)nonce)[0],
		((uint32_t*)nonce)[1]
	};

	for (iters = 0; iters < inlen/(BPI*64); iters++)
		{
#if GPR_TOO
		register unsigned x0, x1, x2, x3, x4, x5, x6, x7, x8,
				  x9, x10, x11, x12, x13, x14, x15;
#endif
#if VBPI > 2
		vec v8,v9,v10,v11;
#endif
#if VBPI > 3
		vec v12,v13,v14,v15;
#endif

		vec v0,v1,v2,v3,v4,v5,v6,v7;
		v4 = v0 = s0; v5 = v1 = s1; v6 = v2 = s2; v3 = s3;
		v7 = v3 + ONE;
#if VBPI > 2
		v8 = v4; v9 = v5; v10 = v6;
		v11 =  v7 + ONE;
#endif
#if VBPI > 3
		v12 = v8; v13 = v9; v14 = v10;
		v15 = v11 + ONE;
#endif
#if GPR_TOO
		x0 = chacha_const[0]; x1 = chacha_const[1];
		x2 = chacha_const[2]; x3 = chacha_const[3];
		x4 = kp[0]; x5 = kp[1]; x6  = kp[2]; x7  = kp[3];
		x8 = kp[4]; x9 = kp[5]; x10 = kp[6]; x11 = kp[7];
		x12 = counter+BPI*iters+(BPI-1); x13 = 0;
		x14 = np[0]; x15 = np[1];
#endif
		for (i = CHACHA_RNDS/2; i; i--)
			{
			DQROUND_VECTORS(v0,v1,v2,v3)
			DQROUND_VECTORS(v4,v5,v6,v7)
#if VBPI > 2
			DQROUND_VECTORS(v8,v9,v10,v11)
#endif
#if VBPI > 3
			DQROUND_VECTORS(v12,v13,v14,v15)
#endif
#if GPR_TOO
			QROUND_WORDS( x0, x4, x8,x12)
			QROUND_WORDS( x1, x5, x9,x13)
			QROUND_WORDS( x2, x6,x10,x14)
			QROUND_WORDS( x3, x7,x11,x15)
			QROUND_WORDS( x0, x5,x10,x15)
			QROUND_WORDS( x1, x6,x11,x12)
			QROUND_WORDS( x2, x7, x8,x13)
			QROUND_WORDS( x3, x4, x9,x14)
#endif
			}

		WRITE_XOR(ip, op, 0, v0+s0, v1+s1, v2+s2, v3+s3)
		s3 += ONE;
		WRITE_XOR(ip, op, 16, v4+s0, v5+s1, v6+s2, v7+s3)
		s3 += ONE;
#if VBPI > 2
		WRITE_XOR(ip, op, 32, v8+s0, v9+s1, v10+s2, v11+s3)
		s3 += ONE;
#endif
#if VBPI > 3
		WRITE_XOR(ip, op, 48, v12+s0, v13+s1, v14+s2, v15+s3)
		s3 += ONE;
#endif
		ip += VBPI*16;
		op += VBPI*16;
#if GPR_TOO
		op[0]  = REVW_BE(REVW_BE(ip[0])  ^ (x0  + chacha_const[0]));
		op[1]  = REVW_BE(REVW_BE(ip[1])  ^ (x1  + chacha_const[1]));
		op[2]  = REVW_BE(REVW_BE(ip[2])  ^ (x2  + chacha_const[2]));
		op[3]  = REVW_BE(REVW_BE(ip[3])  ^ (x3  + chacha_const[3]));
		op[4]  = REVW_BE(REVW_BE(ip[4])  ^ (x4  + kp[0]));
		op[5]  = REVW_BE(REVW_BE(ip[5])  ^ (x5  + kp[1]));
		op[6]  = REVW_BE(REVW_BE(ip[6])  ^ (x6  + kp[2]));
		op[7]  = REVW_BE(REVW_BE(ip[7])  ^ (x7  + kp[3]));
		op[8]  = REVW_BE(REVW_BE(ip[8])  ^ (x8  + kp[4]));
		op[9]  = REVW_BE(REVW_BE(ip[9])  ^ (x9  + kp[5]));
		op[10] = REVW_BE(REVW_BE(ip[10]) ^ (x10 + kp[6]));
		op[11] = REVW_BE(REVW_BE(ip[11]) ^ (x11 + kp[7]));
		op[12] = REVW_BE(REVW_BE(ip[12]) ^ (x12 + counter+BPI*iters+(BPI-1)));
		op[13] = REVW_BE(REVW_BE(ip[13]) ^ (x13));
		op[14] = REVW_BE(REVW_BE(ip[14]) ^ (x14 + np[0]));
		op[15] = REVW_BE(REVW_BE(ip[15]) ^ (x15 + np[1]));
		s3 += ONE;
		ip += 16;
		op += 16;
#endif
		}

	for (iters = inlen%(BPI*64)/64; iters != 0; iters--)
		{
		vec v0 = s0, v1 = s1, v2 = s2, v3 = s3;
		for (i = CHACHA_RNDS/2; i; i--)
			{
			DQROUND_VECTORS(v0,v1,v2,v3);
			}
		WRITE_XOR(ip, op, 0, v0+s0, v1+s1, v2+s2, v3+s3)
		s3 += ONE;
		ip += 16;
		op += 16;
		}

	inlen = inlen % 64;
	if (inlen)
		{
		__attribute__ ((aligned (16))) vec buf[4];
		vec v0,v1,v2,v3;
		v0 = s0; v1 = s1; v2 = s2; v3 = s3;
		for (i = CHACHA_RNDS/2; i; i--)
			{
			DQROUND_VECTORS(v0,v1,v2,v3);
			}

		if (inlen >= 16)
			{
			STORE(op + 0, LOAD(ip + 0) ^ REVV_BE(v0 + s0));
			if (inlen >= 32)
				{
				STORE(op + 4, LOAD(ip + 4) ^ REVV_BE(v1 + s1));
				if (inlen >= 48)
					{
					STORE(op + 8, LOAD(ip +  8) ^
						      REVV_BE(v2 + s2));
					buf[3] = REVV_BE(v3 + s3);
					}
				else
					buf[2] = REVV_BE(v2 + s2);
				}
			else
				buf[1] = REVV_BE(v1 + s1);
			}
		else
			buf[0] = REVV_BE(v0 + s0);

		for (i=inlen & ~15; i<inlen; i++)
			((char *)op)[i] = ((char *)ip)[i] ^ ((char *)buf)[i];
		}
	}

#endif /* ASM_GEN || !OPENSSL_WINDOWS && (OPENSSL_X86_64 || OPENSSL_X86) && SSE2 */