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yespower-ref.c
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yespower-ref.c
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/*-
* Copyright 2009 Colin Percival
* Copyright 2013-2019 Alexander Peslyak
* All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions
* are met:
* 1. Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* 2. Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.
*
* THIS SOFTWARE IS PROVIDED BY THE AUTHOR AND CONTRIBUTORS ``AS IS'' AND
* ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
* IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
* ARE DISCLAIMED. IN NO EVENT SHALL THE AUTHOR OR CONTRIBUTORS BE LIABLE
* FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
* DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
* OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
* HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
* LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
* OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
* SUCH DAMAGE.
*
* This file was originally written by Colin Percival as part of the Tarsnap
* online backup system.
*
* This is a proof-of-work focused fork of yescrypt, including reference and
* cut-down implementation of the obsolete yescrypt 0.5 (based off its first
* submission to PHC back in 2014) and a new proof-of-work specific variation
* known as yespower 1.0. The former is intended as an upgrade for
* cryptocurrencies that already use yescrypt 0.5 and the latter may be used
* as a further upgrade (hard fork) by those and other cryptocurrencies. The
* version of algorithm to use is requested through parameters, allowing for
* both algorithms to co-exist in client and miner implementations (such as in
* preparation for a hard-fork).
*
* This is the reference implementation. Its purpose is to provide a simple
* human- and machine-readable specification that implementations intended
* for actual use should be tested against. It is deliberately mostly not
* optimized, and it is not meant to be used in production. Instead, use
* yespower-opt.c.
*/
#warning "This reference implementation is deliberately mostly not optimized. Use yespower-opt.c instead unless you're testing (against) the reference implementation on purpose."
#include <errno.h>
#include <stdint.h>
#include <stdlib.h>
#include <string.h>
#include "sha256.h"
#include "sysendian.h"
#include "yespower.h"
static void blkcpy(uint32_t *dst, const uint32_t *src, size_t count)
{
do {
*dst++ = *src++;
} while (--count);
}
static void blkxor(uint32_t *dst, const uint32_t *src, size_t count)
{
do {
*dst++ ^= *src++;
} while (--count);
}
/**
* salsa20(B):
* Apply the Salsa20 core to the provided block.
*/
static void salsa20(uint32_t B[16], uint32_t rounds)
{
uint32_t x[16];
size_t i;
/* SIMD unshuffle */
for (i = 0; i < 16; i++)
x[i * 5 % 16] = B[i];
for (i = 0; i < rounds; i += 2) {
#define R(a,b) (((a) << (b)) | ((a) >> (32 - (b))))
/* Operate on columns */
x[ 4] ^= R(x[ 0]+x[12], 7); x[ 8] ^= R(x[ 4]+x[ 0], 9);
x[12] ^= R(x[ 8]+x[ 4],13); x[ 0] ^= R(x[12]+x[ 8],18);
x[ 9] ^= R(x[ 5]+x[ 1], 7); x[13] ^= R(x[ 9]+x[ 5], 9);
x[ 1] ^= R(x[13]+x[ 9],13); x[ 5] ^= R(x[ 1]+x[13],18);
x[14] ^= R(x[10]+x[ 6], 7); x[ 2] ^= R(x[14]+x[10], 9);
x[ 6] ^= R(x[ 2]+x[14],13); x[10] ^= R(x[ 6]+x[ 2],18);
x[ 3] ^= R(x[15]+x[11], 7); x[ 7] ^= R(x[ 3]+x[15], 9);
x[11] ^= R(x[ 7]+x[ 3],13); x[15] ^= R(x[11]+x[ 7],18);
/* Operate on rows */
x[ 1] ^= R(x[ 0]+x[ 3], 7); x[ 2] ^= R(x[ 1]+x[ 0], 9);
x[ 3] ^= R(x[ 2]+x[ 1],13); x[ 0] ^= R(x[ 3]+x[ 2],18);
x[ 6] ^= R(x[ 5]+x[ 4], 7); x[ 7] ^= R(x[ 6]+x[ 5], 9);
x[ 4] ^= R(x[ 7]+x[ 6],13); x[ 5] ^= R(x[ 4]+x[ 7],18);
x[11] ^= R(x[10]+x[ 9], 7); x[ 8] ^= R(x[11]+x[10], 9);
x[ 9] ^= R(x[ 8]+x[11],13); x[10] ^= R(x[ 9]+x[ 8],18);
x[12] ^= R(x[15]+x[14], 7); x[13] ^= R(x[12]+x[15], 9);
x[14] ^= R(x[13]+x[12],13); x[15] ^= R(x[14]+x[13],18);
#undef R
}
/* SIMD shuffle */
for (i = 0; i < 16; i++)
B[i] += x[i * 5 % 16];
}
/**
* blockmix_salsa(B):
* Compute B = BlockMix_{salsa20, 1}(B). The input B must be 128 bytes in
* length.
*/
static void blockmix_salsa(uint32_t *B, uint32_t rounds)
{
uint32_t X[16];
size_t i;
/* 1: X <-- B_{2r - 1} */
blkcpy(X, &B[16], 16);
/* 2: for i = 0 to 2r - 1 do */
for (i = 0; i < 2; i++) {
/* 3: X <-- H(X xor B_i) */
blkxor(X, &B[i * 16], 16);
salsa20(X, rounds);
/* 4: Y_i <-- X */
/* 6: B' <-- (Y_0, Y_2 ... Y_{2r-2}, Y_1, Y_3 ... Y_{2r-1}) */
blkcpy(&B[i * 16], X, 16);
}
}
/*
* These are tunable, but they must meet certain constraints and are part of
* what defines a yespower version.
*/
#define PWXsimple 2
#define PWXgather 4
/* Version 0.5 */
#define PWXrounds_0_5 6
#define Swidth_0_5 8
/* Version 1.0 */
#define PWXrounds_1_0 3
#define Swidth_1_0 11
/* Derived values. Not tunable on their own. */
#define PWXbytes (PWXgather * PWXsimple * 8)
#define PWXwords (PWXbytes / sizeof(uint32_t))
#define rmin ((PWXbytes + 127) / 128)
/* Runtime derived values. Not tunable on their own. */
#define Swidth_to_Sbytes1(Swidth) ((1 << Swidth) * PWXsimple * 8)
#define Swidth_to_Smask(Swidth) (((1 << Swidth) - 1) * PWXsimple * 8)
typedef struct {
yespower_version_t version;
uint32_t salsa20_rounds;
uint32_t PWXrounds, Swidth, Sbytes, Smask;
uint32_t *S;
uint32_t (*S0)[2], (*S1)[2], (*S2)[2];
size_t w;
} pwxform_ctx_t;
/**
* pwxform(B):
* Transform the provided block using the provided S-boxes.
*/
static void pwxform(uint32_t *B, pwxform_ctx_t *ctx)
{
uint32_t (*X)[PWXsimple][2] = (uint32_t (*)[PWXsimple][2])B;
uint32_t (*S0)[2] = ctx->S0, (*S1)[2] = ctx->S1, (*S2)[2] = ctx->S2;
uint32_t Smask = ctx->Smask;
size_t w = ctx->w;
size_t i, j, k;
/* 1: for i = 0 to PWXrounds - 1 do */
for (i = 0; i < ctx->PWXrounds; i++) {
/* 2: for j = 0 to PWXgather - 1 do */
for (j = 0; j < PWXgather; j++) {
uint32_t xl = X[j][0][0];
uint32_t xh = X[j][0][1];
uint32_t (*p0)[2], (*p1)[2];
/* 3: p0 <-- (lo(B_{j,0}) & Smask) / (PWXsimple * 8) */
p0 = S0 + (xl & Smask) / sizeof(*S0);
/* 4: p1 <-- (hi(B_{j,0}) & Smask) / (PWXsimple * 8) */
p1 = S1 + (xh & Smask) / sizeof(*S1);
/* 5: for k = 0 to PWXsimple - 1 do */
for (k = 0; k < PWXsimple; k++) {
uint64_t x, s0, s1;
/* 6: B_{j,k} <-- (hi(B_{j,k}) * lo(B_{j,k}) + S0_{p0,k}) xor S1_{p1,k} */
s0 = ((uint64_t)p0[k][1] << 32) + p0[k][0];
s1 = ((uint64_t)p1[k][1] << 32) + p1[k][0];
xl = X[j][k][0];
xh = X[j][k][1];
x = (uint64_t)xh * xl;
x += s0;
x ^= s1;
X[j][k][0] = x;
X[j][k][1] = x >> 32;
}
if (ctx->version != YESPOWER_0_5 &&
(i == 0 || j < PWXgather / 2)) {
if (j & 1) {
for (k = 0; k < PWXsimple; k++) {
S1[w][0] = X[j][k][0];
S1[w][1] = X[j][k][1];
w++;
}
} else {
for (k = 0; k < PWXsimple; k++) {
S0[w + k][0] = X[j][k][0];
S0[w + k][1] = X[j][k][1];
}
}
}
}
}
if (ctx->version != YESPOWER_0_5) {
/* 14: (S0, S1, S2) <-- (S2, S0, S1) */
ctx->S0 = S2;
ctx->S1 = S0;
ctx->S2 = S1;
/* 15: w <-- w mod 2^Swidth */
ctx->w = w & ((1 << ctx->Swidth) * PWXsimple - 1);
}
}
/**
* blockmix_pwxform(B, ctx, r):
* Compute B = BlockMix_pwxform{salsa20, ctx, r}(B). The input B must be
* 128r bytes in length.
*/
static void blockmix_pwxform(uint32_t *B, pwxform_ctx_t *ctx, size_t r)
{
uint32_t X[PWXwords];
size_t r1, i;
/* Convert 128-byte blocks to PWXbytes blocks */
/* 1: r_1 <-- 128r / PWXbytes */
r1 = 128 * r / PWXbytes;
/* 2: X <-- B'_{r_1 - 1} */
blkcpy(X, &B[(r1 - 1) * PWXwords], PWXwords);
/* 3: for i = 0 to r_1 - 1 do */
for (i = 0; i < r1; i++) {
/* 4: if r_1 > 1 */
if (r1 > 1) {
/* 5: X <-- X xor B'_i */
blkxor(X, &B[i * PWXwords], PWXwords);
}
/* 7: X <-- pwxform(X) */
pwxform(X, ctx);
/* 8: B'_i <-- X */
blkcpy(&B[i * PWXwords], X, PWXwords);
}
/* 10: i <-- floor((r_1 - 1) * PWXbytes / 64) */
i = (r1 - 1) * PWXbytes / 64;
/* 11: B_i <-- H(B_i) */
salsa20(&B[i * 16], ctx->salsa20_rounds);
#if 1 /* No-op with our current pwxform settings, but do it to make sure */
/* 12: for i = i + 1 to 2r - 1 do */
for (i++; i < 2 * r; i++) {
/* 13: B_i <-- H(B_i xor B_{i-1}) */
blkxor(&B[i * 16], &B[(i - 1) * 16], 16);
salsa20(&B[i * 16], ctx->salsa20_rounds);
}
#endif
}
/**
* integerify(B, r):
* Return the result of parsing B_{2r-1} as a little-endian integer.
*/
static uint32_t integerify(const uint32_t *B, size_t r)
{
/*
* Our 32-bit words are in host byte order. Also, they are SIMD-shuffled, but
* we only care about the least significant 32 bits anyway.
*/
const uint32_t *X = &B[(2 * r - 1) * 16];
return X[0];
}
/**
* p2floor(x):
* Largest power of 2 not greater than argument.
*/
static uint32_t p2floor(uint32_t x)
{
uint32_t y;
while ((y = x & (x - 1)))
x = y;
return x;
}
/**
* wrap(x, i):
* Wrap x to the range 0 to i-1.
*/
static uint32_t wrap(uint32_t x, uint32_t i)
{
uint32_t n = p2floor(i);
return (x & (n - 1)) + (i - n);
}
/**
* smix1(B, r, N, V, X, ctx):
* Compute first loop of B = SMix_r(B, N). The input B must be 128r bytes in
* length; the temporary storage V must be 128rN bytes in length; the temporary
* storage X must be 128r bytes in length.
*/
static void smix1(uint32_t *B, size_t r, uint32_t N,
uint32_t *V, uint32_t *X, pwxform_ctx_t *ctx)
{
size_t s = 32 * r;
uint32_t i, j;
size_t k;
/* 1: X <-- B */
for (k = 0; k < 2 * r; k++)
for (i = 0; i < 16; i++)
X[k * 16 + i] = le32dec(&B[k * 16 + (i * 5 % 16)]);
if (ctx->version != YESPOWER_0_5) {
for (k = 1; k < r; k++) {
blkcpy(&X[k * 32], &X[(k - 1) * 32], 32);
blockmix_pwxform(&X[k * 32], ctx, 1);
}
}
/* 2: for i = 0 to N - 1 do */
for (i = 0; i < N; i++) {
/* 3: V_i <-- X */
blkcpy(&V[i * s], X, s);
if (i > 1) {
/* j <-- Wrap(Integerify(X), i) */
j = wrap(integerify(X, r), i);
/* X <-- X xor V_j */
blkxor(X, &V[j * s], s);
}
/* 4: X <-- H(X) */
if (V != ctx->S)
blockmix_pwxform(X, ctx, r);
else
blockmix_salsa(X, ctx->salsa20_rounds);
}
/* B' <-- X */
for (k = 0; k < 2 * r; k++)
for (i = 0; i < 16; i++)
le32enc(&B[k * 16 + (i * 5 % 16)], X[k * 16 + i]);
}
/**
* smix2(B, r, N, Nloop, V, X, ctx):
* Compute second loop of B = SMix_r(B, N). The input B must be 128r bytes in
* length; the temporary storage V must be 128rN bytes in length; the temporary
* storage X must be 128r bytes in length. The value N must be a power of 2
* greater than 1.
*/
static void smix2(uint32_t *B, size_t r, uint32_t N, uint32_t Nloop,
uint32_t *V, uint32_t *X, pwxform_ctx_t *ctx)
{
size_t s = 32 * r;
uint32_t i, j;
size_t k;
/* X <-- B */
for (k = 0; k < 2 * r; k++)
for (i = 0; i < 16; i++)
X[k * 16 + i] = le32dec(&B[k * 16 + (i * 5 % 16)]);
/* 6: for i = 0 to N - 1 do */
for (i = 0; i < Nloop; i++) {
/* 7: j <-- Integerify(X) mod N */
j = integerify(X, r) & (N - 1);
/* 8.1: X <-- X xor V_j */
blkxor(X, &V[j * s], s);
/* V_j <-- X */
if (Nloop != 2)
blkcpy(&V[j * s], X, s);
/* 8.2: X <-- H(X) */
blockmix_pwxform(X, ctx, r);
}
/* 10: B' <-- X */
for (k = 0; k < 2 * r; k++)
for (i = 0; i < 16; i++)
le32enc(&B[k * 16 + (i * 5 % 16)], X[k * 16 + i]);
}
/**
* smix(B, r, N, p, t, V, X, ctx):
* Compute B = SMix_r(B, N). The input B must be 128rp bytes in length; the
* temporary storage V must be 128rN bytes in length; the temporary storage
* X must be 128r bytes in length. The value N must be a power of 2 and at
* least 16.
*/
static void smix(uint32_t *B, size_t r, uint32_t N,
uint32_t *V, uint32_t *X, pwxform_ctx_t *ctx)
{
uint32_t Nloop_all = (N + 2) / 3; /* 1/3, round up */
uint32_t Nloop_rw = Nloop_all;
Nloop_all++; Nloop_all &= ~(uint32_t)1; /* round up to even */
if (ctx->version == YESPOWER_0_5) {
Nloop_rw &= ~(uint32_t)1; /* round down to even */
} else {
Nloop_rw++; Nloop_rw &= ~(uint32_t)1; /* round up to even */
}
smix1(B, 1, ctx->Sbytes / 128, ctx->S, X, ctx);
smix1(B, r, N, V, X, ctx);
smix2(B, r, N, Nloop_rw /* must be > 2 */, V, X, ctx);
smix2(B, r, N, Nloop_all - Nloop_rw /* 0 or 2 */, V, X, ctx);
}
/**
* yespower(local, src, srclen, params, dst):
* Compute yespower(src[0 .. srclen - 1], N, r), to be checked for "< target".
*
* Return 0 on success; or -1 on error.
*/
int yespower(yespower_local_t *local,
const uint8_t *src, size_t srclen,
const yespower_params_t *params, yespower_binary_t *dst)
{
yespower_version_t version = params->version;
uint32_t N = params->N;
uint32_t r = params->r;
const uint8_t *pers = params->pers;
size_t perslen = params->perslen;
int retval = -1;
size_t B_size, V_size;
uint32_t *B, *V, *X, *S;
pwxform_ctx_t ctx;
uint32_t sha256[8];
memset(dst, 0xff, sizeof(*dst));
/* Sanity-check parameters */
if ((version != YESPOWER_0_5 && version != YESPOWER_1_0) ||
N < 1024 || N > 512 * 1024 || r < 8 || r > 32 ||
(N & (N - 1)) != 0 || r < rmin ||
(!pers && perslen)) {
errno = EINVAL;
return -1;
}
/* Allocate memory */
B_size = (size_t)128 * r;
V_size = B_size * N;
if ((V = malloc(V_size)) == NULL)
return -1;
if ((B = malloc(B_size)) == NULL)
goto free_V;
if ((X = malloc(B_size)) == NULL)
goto free_B;
ctx.version = version;
if (version == YESPOWER_0_5) {
ctx.salsa20_rounds = 8;
ctx.PWXrounds = PWXrounds_0_5;
ctx.Swidth = Swidth_0_5;
ctx.Sbytes = 2 * Swidth_to_Sbytes1(ctx.Swidth);
} else {
ctx.salsa20_rounds = 2;
ctx.PWXrounds = PWXrounds_1_0;
ctx.Swidth = Swidth_1_0;
ctx.Sbytes = 3 * Swidth_to_Sbytes1(ctx.Swidth);
}
if ((S = malloc(ctx.Sbytes)) == NULL)
goto free_X;
ctx.S = S;
ctx.S0 = (uint32_t (*)[2])S;
ctx.S1 = ctx.S0 + (1 << ctx.Swidth) * PWXsimple;
ctx.S2 = ctx.S1 + (1 << ctx.Swidth) * PWXsimple;
ctx.Smask = Swidth_to_Smask(ctx.Swidth);
ctx.w = 0;
SHA256_Buf(src, srclen, (uint8_t *)sha256);
if (version != YESPOWER_0_5) {
if (pers) {
src = pers;
srclen = perslen;
} else {
srclen = 0;
}
}
/* 1: (B_0 ... B_{p-1}) <-- PBKDF2(P, S, 1, p * MFLen) */
PBKDF2_SHA256((uint8_t *)sha256, sizeof(sha256),
src, srclen, 1, (uint8_t *)B, B_size);
blkcpy(sha256, B, sizeof(sha256) / sizeof(sha256[0]));
/* 3: B_i <-- MF(B_i, N) */
smix(B, r, N, V, X, &ctx);
if (version == YESPOWER_0_5) {
/* 5: DK <-- PBKDF2(P, B, 1, dkLen) */
PBKDF2_SHA256((uint8_t *)sha256, sizeof(sha256),
(uint8_t *)B, B_size, 1, (uint8_t *)dst, sizeof(*dst));
if (pers) {
HMAC_SHA256_Buf(dst, sizeof(*dst), pers, perslen,
(uint8_t *)sha256);
SHA256_Buf(sha256, sizeof(sha256), (uint8_t *)dst);
}
} else {
HMAC_SHA256_Buf((uint8_t *)B + B_size - 64, 64,
sha256, sizeof(sha256), (uint8_t *)dst);
}
/* Success! */
retval = 0;
/* Free memory */
free(S);
free_X:
free(X);
free_B:
free(B);
free_V:
free(V);
return retval;
}
int yespower_tls(const uint8_t *src, size_t srclen,
const yespower_params_t *params, yespower_binary_t *dst)
{
/* The reference implementation doesn't use thread-local storage */
return yespower(NULL, src, srclen, params, dst);
}
int yespower_init_local(yespower_local_t *local)
{
/* The reference implementation doesn't use the local structure */
local->base = local->aligned = NULL;
local->base_size = local->aligned_size = 0;
return 0;
}
int yespower_free_local(yespower_local_t *local)
{
/* The reference implementation frees its memory in yespower() */
(void)local; /* unused */
return 0;
}