RandomWOW/src/argon2_core.c

/*
Copyright (c) 2018 tevador

This file is part of RandomX.

RandomX is free software: you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation, either version 3 of the License, or
(at your option) any later version.

RandomX is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.

You should have received a copy of the GNU General Public License
along with RandomX.  If not, see<http://www.gnu.org/licenses/>.
*/

/* Original code from Argon2 reference source code package used under CC0 Licence
 * https://github.com/P-H-C/phc-winner-argon2
 * Copyright 2015
 * Daniel Dinu, Dmitry Khovratovich, Jean-Philippe Aumasson, and Samuel Neves
*/

 /*For memory wiping*/
#ifdef _MSC_VER
#include <windows.h>
#include <winbase.h> /* For SecureZeroMemory */
#endif
#if defined __STDC_LIB_EXT1__
#define __STDC_WANT_LIB_EXT1__ 1
#endif
#define VC_GE_2005(version) (version >= 1400)

#include <stdio.h>
#include <stdlib.h>
#include <string.h>

#include "argon2_core.h"
#include "blake2/blake2.h"
#include "blake2/blake2-impl.h"

#ifdef GENKAT
#include "genkat.h"
#endif

#if defined(__clang__)
#if __has_attribute(optnone)
#define NOT_OPTIMIZED __attribute__((optnone))
#endif
#elif defined(__GNUC__)
#define GCC_VERSION                                                            \
    (__GNUC__ * 10000 + __GNUC_MINOR__ * 100 + __GNUC_PATCHLEVEL__)
#if GCC_VERSION >= 40400
#define NOT_OPTIMIZED __attribute__((optimize("O0")))
#endif
#endif
#ifndef NOT_OPTIMIZED
#define NOT_OPTIMIZED
#endif

/***************Instance and Position constructors**********/
void init_block_value(block *b, uint8_t in) { memset(b->v, in, sizeof(b->v)); }

void copy_block(block *dst, const block *src) {
	memcpy(dst->v, src->v, sizeof(uint64_t) * ARGON2_QWORDS_IN_BLOCK);
}

void xor_block(block *dst, const block *src) {
	int i;
	for (i = 0; i < ARGON2_QWORDS_IN_BLOCK; ++i) {
		dst->v[i] ^= src->v[i];
	}
}

static void load_block(block *dst, const void *input) {
	unsigned i;
	for (i = 0; i < ARGON2_QWORDS_IN_BLOCK; ++i) {
		dst->v[i] = load64((const uint8_t *)input + i * sizeof(dst->v[i]));
	}
}

static void store_block(void *output, const block *src) {
	unsigned i;
	for (i = 0; i < ARGON2_QWORDS_IN_BLOCK; ++i) {
		store64((uint8_t *)output + i * sizeof(src->v[i]), src->v[i]);
	}
}

/***************Memory functions*****************/

int allocate_memory(const argon2_context *context, uint8_t **memory,
	size_t num, size_t size) {
	size_t memory_size = num * size;
	if (memory == NULL) {
		return ARGON2_MEMORY_ALLOCATION_ERROR;
	}

	/* 1. Check for multiplication overflow */
	if (size != 0 && memory_size / size != num) {
		return ARGON2_MEMORY_ALLOCATION_ERROR;
	}

	/* 2. Try to allocate with appropriate allocator */
	if (context->allocate_cbk) {
		(context->allocate_cbk)(memory, memory_size);
	}
	else {
		*memory = (uint8_t*)malloc(memory_size);
	}

	if (*memory == NULL) {
		return ARGON2_MEMORY_ALLOCATION_ERROR;
	}

	return ARGON2_OK;
}

void free_memory(const argon2_context *context, uint8_t *memory,
	size_t num, size_t size) {
	size_t memory_size = num * size;
	clear_internal_memory(memory, memory_size);
	if (context->free_cbk) {
		(context->free_cbk)(memory, memory_size);
	}
	else {
		free(memory);
	}
}

void NOT_OPTIMIZED secure_wipe_memory(void *v, size_t n) {
#if defined(_MSC_VER) && VC_GE_2005(_MSC_VER)
	SecureZeroMemory(v, n);
#elif defined memset_s
	memset_s(v, n, 0, n);
#elif defined(__OpenBSD__)
	explicit_bzero(v, n);
#else
	static void *(*const volatile memset_sec)(void *, int, size_t) = &memset;
	memset_sec(v, 0, n);
#endif
}

/* Memory clear flag defaults to true. */
#define FLAG_clear_internal_memory 0
void clear_internal_memory(void *v, size_t n) {
	if (FLAG_clear_internal_memory && v) {
		secure_wipe_memory(v, n);
	}
}

uint32_t index_alpha(const argon2_instance_t *instance,
	const argon2_position_t *position, uint32_t pseudo_rand,
	int same_lane) {
	/*
	 * Pass 0:
	 *      This lane : all already finished segments plus already constructed
	 * blocks in this segment
	 *      Other lanes : all already finished segments
	 * Pass 1+:
	 *      This lane : (SYNC_POINTS - 1) last segments plus already constructed
	 * blocks in this segment
	 *      Other lanes : (SYNC_POINTS - 1) last segments
	 */
	uint32_t reference_area_size;
	uint64_t relative_position;
	uint32_t start_position, absolute_position;

	if (0 == position->pass) {
		/* First pass */
		if (0 == position->slice) {
			/* First slice */
			reference_area_size =
				position->index - 1; /* all but the previous */
		}
		else {
			if (same_lane) {
				/* The same lane => add current segment */
				reference_area_size =
					position->slice * instance->segment_length +
					position->index - 1;
			}
			else {
				reference_area_size =
					position->slice * instance->segment_length +
					((position->index == 0) ? (-1) : 0);
			}
		}
	}
	else {
		/* Second pass */
		if (same_lane) {
			reference_area_size = instance->lane_length -
				instance->segment_length + position->index -
				1;
		}
		else {
			reference_area_size = instance->lane_length -
				instance->segment_length +
				((position->index == 0) ? (-1) : 0);
		}
	}

	/* 1.2.4. Mapping pseudo_rand to 0..<reference_area_size-1> and produce
	 * relative position */
	relative_position = pseudo_rand;
	relative_position = relative_position * relative_position >> 32;
	relative_position = reference_area_size - 1 -
		(reference_area_size * relative_position >> 32);

	/* 1.2.5 Computing starting position */
	start_position = 0;

	if (0 != position->pass) {
		start_position = (position->slice == ARGON2_SYNC_POINTS - 1)
			? 0
			: (position->slice + 1) * instance->segment_length;
	}

	/* 1.2.6. Computing absolute position */
	absolute_position = (start_position + relative_position) %
		instance->lane_length; /* absolute position */
	return absolute_position;
}

/* Single-threaded version for p=1 case */
static int fill_memory_blocks_st(argon2_instance_t *instance) {
	uint32_t r, s, l;

	for (r = 0; r < instance->passes; ++r) {
		for (s = 0; s < ARGON2_SYNC_POINTS; ++s) {
			for (l = 0; l < instance->lanes; ++l) {
				argon2_position_t position = { r, l, (uint8_t)s, 0 };
				fill_segment(instance, position);
			}
		}
#ifdef GENKAT
		internal_kat(instance, r); /* Print all memory blocks */
#endif
	}
	return ARGON2_OK;
}

int fill_memory_blocks(argon2_instance_t *instance) {
	if (instance == NULL || instance->lanes == 0) {
		return ARGON2_INCORRECT_PARAMETER;
	}
	return fill_memory_blocks_st(instance);
}

int validate_inputs(const argon2_context *context) {
	if (NULL == context) {
		return ARGON2_INCORRECT_PARAMETER;
	}

	if (NULL == context->out) {
		return ARGON2_OUTPUT_PTR_NULL;
	}

	/* Validate output length */
	if (ARGON2_MIN_OUTLEN > context->outlen) {
		return ARGON2_OUTPUT_TOO_SHORT;
	}

	if (ARGON2_MAX_OUTLEN < context->outlen) {
		return ARGON2_OUTPUT_TOO_LONG;
	}

	/* Validate password (required param) */
	if (NULL == context->pwd) {
		if (0 != context->pwdlen) {
			return ARGON2_PWD_PTR_MISMATCH;
		}
	}

	if (ARGON2_MIN_PWD_LENGTH > context->pwdlen) {
		return ARGON2_PWD_TOO_SHORT;
	}

	if (ARGON2_MAX_PWD_LENGTH < context->pwdlen) {
		return ARGON2_PWD_TOO_LONG;
	}

	/* Validate salt (required param) */
	if (NULL == context->salt) {
		if (0 != context->saltlen) {
			return ARGON2_SALT_PTR_MISMATCH;
		}
	}

	if (ARGON2_MIN_SALT_LENGTH > context->saltlen) {
		return ARGON2_SALT_TOO_SHORT;
	}

	if (ARGON2_MAX_SALT_LENGTH < context->saltlen) {
		return ARGON2_SALT_TOO_LONG;
	}

	/* Validate secret (optional param) */
	if (NULL == context->secret) {
		if (0 != context->secretlen) {
			return ARGON2_SECRET_PTR_MISMATCH;
		}
	}
	else {
		if (ARGON2_MIN_SECRET > context->secretlen) {
			return ARGON2_SECRET_TOO_SHORT;
		}
		if (ARGON2_MAX_SECRET < context->secretlen) {
			return ARGON2_SECRET_TOO_LONG;
		}
	}

	/* Validate associated data (optional param) */
	if (NULL == context->ad) {
		if (0 != context->adlen) {
			return ARGON2_AD_PTR_MISMATCH;
		}
	}
	else {
		if (ARGON2_MIN_AD_LENGTH > context->adlen) {
			return ARGON2_AD_TOO_SHORT;
		}
		if (ARGON2_MAX_AD_LENGTH < context->adlen) {
			return ARGON2_AD_TOO_LONG;
		}
	}

	/* Validate memory cost */
	if (ARGON2_MIN_MEMORY > context->m_cost) {
		return ARGON2_MEMORY_TOO_LITTLE;
	}

	if (ARGON2_MAX_MEMORY < context->m_cost) {
		return ARGON2_MEMORY_TOO_MUCH;
	}

	if (context->m_cost < 8 * context->lanes) {
		return ARGON2_MEMORY_TOO_LITTLE;
	}

	/* Validate time cost */
	if (ARGON2_MIN_TIME > context->t_cost) {
		return ARGON2_TIME_TOO_SMALL;
	}

	if (ARGON2_MAX_TIME < context->t_cost) {
		return ARGON2_TIME_TOO_LARGE;
	}

	/* Validate lanes */
	if (ARGON2_MIN_LANES > context->lanes) {
		return ARGON2_LANES_TOO_FEW;
	}

	if (ARGON2_MAX_LANES < context->lanes) {
		return ARGON2_LANES_TOO_MANY;
	}

	/* Validate threads */
	if (ARGON2_MIN_THREADS > context->threads) {
		return ARGON2_THREADS_TOO_FEW;
	}

	if (ARGON2_MAX_THREADS < context->threads) {
		return ARGON2_THREADS_TOO_MANY;
	}

	if (NULL != context->allocate_cbk && NULL == context->free_cbk) {
		return ARGON2_FREE_MEMORY_CBK_NULL;
	}

	if (NULL == context->allocate_cbk && NULL != context->free_cbk) {
		return ARGON2_ALLOCATE_MEMORY_CBK_NULL;
	}

	return ARGON2_OK;
}

void fill_first_blocks(uint8_t *blockhash, const argon2_instance_t *instance) {
	uint32_t l;
	/* Make the first and second block in each lane as G(H0||0||i) or
	   G(H0||1||i) */
	uint8_t blockhash_bytes[ARGON2_BLOCK_SIZE];
	for (l = 0; l < instance->lanes; ++l) {

		store32(blockhash + ARGON2_PREHASH_DIGEST_LENGTH, 0);
		store32(blockhash + ARGON2_PREHASH_DIGEST_LENGTH + 4, l);
		blake2b_long(blockhash_bytes, ARGON2_BLOCK_SIZE, blockhash,
			ARGON2_PREHASH_SEED_LENGTH);
		load_block(&instance->memory[l * instance->lane_length + 0],
			blockhash_bytes);

		store32(blockhash + ARGON2_PREHASH_DIGEST_LENGTH, 1);
		blake2b_long(blockhash_bytes, ARGON2_BLOCK_SIZE, blockhash,
			ARGON2_PREHASH_SEED_LENGTH);
		load_block(&instance->memory[l * instance->lane_length + 1],
			blockhash_bytes);
	}
	clear_internal_memory(blockhash_bytes, ARGON2_BLOCK_SIZE);
}

void initial_hash(uint8_t *blockhash, argon2_context *context, argon2_type type) {
	blake2b_state BlakeHash;
	uint8_t value[sizeof(uint32_t)];

	if (NULL == context || NULL == blockhash) {
		return;
	}

	blake2b_init(&BlakeHash, ARGON2_PREHASH_DIGEST_LENGTH);

	store32(&value, context->lanes);
	blake2b_update(&BlakeHash, (const uint8_t *)&value, sizeof(value));

	store32(&value, context->outlen);
	blake2b_update(&BlakeHash, (const uint8_t *)&value, sizeof(value));

	store32(&value, context->m_cost);
	blake2b_update(&BlakeHash, (const uint8_t *)&value, sizeof(value));

	store32(&value, context->t_cost);
	blake2b_update(&BlakeHash, (const uint8_t *)&value, sizeof(value));

	store32(&value, context->version);
	blake2b_update(&BlakeHash, (const uint8_t *)&value, sizeof(value));

	store32(&value, (uint32_t)type);
	blake2b_update(&BlakeHash, (const uint8_t *)&value, sizeof(value));

	store32(&value, context->pwdlen);
	blake2b_update(&BlakeHash, (const uint8_t *)&value, sizeof(value));

	if (context->pwd != NULL) {
		blake2b_update(&BlakeHash, (const uint8_t *)context->pwd,
			context->pwdlen);

		if (context->flags & ARGON2_FLAG_CLEAR_PASSWORD) {
			secure_wipe_memory(context->pwd, context->pwdlen);
			context->pwdlen = 0;
		}
	}

	store32(&value, context->saltlen);
	blake2b_update(&BlakeHash, (const uint8_t *)&value, sizeof(value));

	if (context->salt != NULL) {
		blake2b_update(&BlakeHash, (const uint8_t *)context->salt, context->saltlen);
	}

	store32(&value, context->secretlen);
	blake2b_update(&BlakeHash, (const uint8_t *)&value, sizeof(value));

	if (context->secret != NULL) {
		blake2b_update(&BlakeHash, (const uint8_t *)context->secret,
			context->secretlen);

		if (context->flags & ARGON2_FLAG_CLEAR_SECRET) {
			secure_wipe_memory(context->secret, context->secretlen);
			context->secretlen = 0;
		}
	}

	store32(&value, context->adlen);
	blake2b_update(&BlakeHash, (const uint8_t *)&value, sizeof(value));

	if (context->ad != NULL) {
		blake2b_update(&BlakeHash, (const uint8_t *)context->ad,
			context->adlen);
	}

	blake2b_final(&BlakeHash, blockhash, ARGON2_PREHASH_DIGEST_LENGTH);
}

int argon_initialize(argon2_instance_t *instance, argon2_context *context) {
	uint8_t blockhash[ARGON2_PREHASH_SEED_LENGTH];
	int result = ARGON2_OK;

	if (instance == NULL || context == NULL)
		return ARGON2_INCORRECT_PARAMETER;
	instance->context_ptr = context;

	/* 1. Memory allocation */
	/*result = allocate_memory(context, (uint8_t **)&(instance->memory), instance->memory_blocks, sizeof(block));
	if (result != ARGON2_OK) {
		return result;
	}*/

	/* 2. Initial hashing */
	/* H_0 + 8 extra bytes to produce the first blocks */
	/* uint8_t blockhash[ARGON2_PREHASH_SEED_LENGTH]; */
	/* Hashing all inputs */
	initial_hash(blockhash, context, instance->type);
	/* Zeroing 8 extra bytes */
	clear_internal_memory(blockhash + ARGON2_PREHASH_DIGEST_LENGTH,
		ARGON2_PREHASH_SEED_LENGTH -
		ARGON2_PREHASH_DIGEST_LENGTH);

	/* 3. Creating first blocks, we always have at least two blocks in a slice
	 */
	fill_first_blocks(blockhash, instance);
	/* Clearing the hash */
	clear_internal_memory(blockhash, ARGON2_PREHASH_SEED_LENGTH);

	return ARGON2_OK;
}