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09d14a0b6c
The Argon2i/id is a password hashing function that won Password Hashing Competiton. It will be (optionally) used in LUKS2 for passworrd-based key derivation. We have to bundle code for now (similar PBKDF2 years ago) because there is yet no usable implementation in common crypto libraries. (Once there is native implementation, cryptsetup will switch to the crypto library version.) For now, we use reference (not optimized but portable) implementation. This patch contains bundled Argon2 algorithm library copied from https://github.com/P-H-C/phc-winner-argon2 For more info see Password Hashing Competition site: https://password-hashing.net/ and draft of RFC document https://datatracker.ietf.org/doc/draft-irtf-cfrg-argon2/ Signed-off-by: Milan Broz <gmazyland@gmail.com>
195 lines
7.1 KiB
C
195 lines
7.1 KiB
C
/*
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* Argon2 reference source code package - reference C implementations
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*
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* Copyright 2015
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* Daniel Dinu, Dmitry Khovratovich, Jean-Philippe Aumasson, and Samuel Neves
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*
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* You may use this work under the terms of a Creative Commons CC0 1.0
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* License/Waiver or the Apache Public License 2.0, at your option. The terms of
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* these licenses can be found at:
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*
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* - CC0 1.0 Universal : http://creativecommons.org/publicdomain/zero/1.0
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* - Apache 2.0 : http://www.apache.org/licenses/LICENSE-2.0
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*
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* You should have received a copy of both of these licenses along with this
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* software. If not, they may be obtained at the above URLs.
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*/
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#include <stdint.h>
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#include <string.h>
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#include <stdlib.h>
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#include "argon2.h"
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#include "core.h"
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#include "blake2/blamka-round-ref.h"
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#include "blake2/blake2-impl.h"
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#include "blake2/blake2.h"
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/*
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* Function fills a new memory block and optionally XORs the old block over the new one.
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* @next_block must be initialized.
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* @param prev_block Pointer to the previous block
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* @param ref_block Pointer to the reference block
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* @param next_block Pointer to the block to be constructed
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* @param with_xor Whether to XOR into the new block (1) or just overwrite (0)
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* @pre all block pointers must be valid
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*/
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static void fill_block(const block *prev_block, const block *ref_block,
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block *next_block, int with_xor) {
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block blockR, block_tmp;
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unsigned i;
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copy_block(&blockR, ref_block);
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xor_block(&blockR, prev_block);
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copy_block(&block_tmp, &blockR);
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/* Now blockR = ref_block + prev_block and block_tmp = ref_block + prev_block */
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if (with_xor) {
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/* Saving the next block contents for XOR over: */
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xor_block(&block_tmp, next_block);
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/* Now blockR = ref_block + prev_block and
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block_tmp = ref_block + prev_block + next_block */
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}
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/* Apply Blake2 on columns of 64-bit words: (0,1,...,15) , then
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(16,17,..31)... finally (112,113,...127) */
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for (i = 0; i < 8; ++i) {
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BLAKE2_ROUND_NOMSG(
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blockR.v[16 * i], blockR.v[16 * i + 1], blockR.v[16 * i + 2],
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blockR.v[16 * i + 3], blockR.v[16 * i + 4], blockR.v[16 * i + 5],
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blockR.v[16 * i + 6], blockR.v[16 * i + 7], blockR.v[16 * i + 8],
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blockR.v[16 * i + 9], blockR.v[16 * i + 10], blockR.v[16 * i + 11],
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blockR.v[16 * i + 12], blockR.v[16 * i + 13], blockR.v[16 * i + 14],
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blockR.v[16 * i + 15]);
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}
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/* Apply Blake2 on rows of 64-bit words: (0,1,16,17,...112,113), then
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(2,3,18,19,...,114,115).. finally (14,15,30,31,...,126,127) */
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for (i = 0; i < 8; i++) {
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BLAKE2_ROUND_NOMSG(
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blockR.v[2 * i], blockR.v[2 * i + 1], blockR.v[2 * i + 16],
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blockR.v[2 * i + 17], blockR.v[2 * i + 32], blockR.v[2 * i + 33],
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blockR.v[2 * i + 48], blockR.v[2 * i + 49], blockR.v[2 * i + 64],
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blockR.v[2 * i + 65], blockR.v[2 * i + 80], blockR.v[2 * i + 81],
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blockR.v[2 * i + 96], blockR.v[2 * i + 97], blockR.v[2 * i + 112],
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blockR.v[2 * i + 113]);
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}
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copy_block(next_block, &block_tmp);
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xor_block(next_block, &blockR);
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}
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static void next_addresses(block *address_block, block *input_block,
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const block *zero_block) {
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input_block->v[6]++;
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fill_block(zero_block, input_block, address_block, 0);
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fill_block(zero_block, address_block, address_block, 0);
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}
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void fill_segment(const argon2_instance_t *instance,
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argon2_position_t position) {
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block *ref_block = NULL, *curr_block = NULL;
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block address_block, input_block, zero_block;
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uint64_t pseudo_rand, ref_index, ref_lane;
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uint32_t prev_offset, curr_offset;
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uint32_t starting_index;
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uint32_t i;
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int data_independent_addressing;
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if (instance == NULL) {
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return;
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}
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data_independent_addressing =
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(instance->type == Argon2_i) ||
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(instance->type == Argon2_id && (position.pass == 0) &&
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(position.slice < ARGON2_SYNC_POINTS / 2));
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if (data_independent_addressing) {
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init_block_value(&zero_block, 0);
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init_block_value(&input_block, 0);
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input_block.v[0] = position.pass;
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input_block.v[1] = position.lane;
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input_block.v[2] = position.slice;
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input_block.v[3] = instance->memory_blocks;
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input_block.v[4] = instance->passes;
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input_block.v[5] = instance->type;
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}
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starting_index = 0;
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if ((0 == position.pass) && (0 == position.slice)) {
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starting_index = 2; /* we have already generated the first two blocks */
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/* Don't forget to generate the first block of addresses: */
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if (data_independent_addressing) {
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next_addresses(&address_block, &input_block, &zero_block);
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}
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}
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/* Offset of the current block */
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curr_offset = position.lane * instance->lane_length +
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position.slice * instance->segment_length + starting_index;
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if (0 == curr_offset % instance->lane_length) {
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/* Last block in this lane */
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prev_offset = curr_offset + instance->lane_length - 1;
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} else {
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/* Previous block */
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prev_offset = curr_offset - 1;
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}
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for (i = starting_index; i < instance->segment_length;
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++i, ++curr_offset, ++prev_offset) {
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/*1.1 Rotating prev_offset if needed */
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if (curr_offset % instance->lane_length == 1) {
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prev_offset = curr_offset - 1;
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}
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/* 1.2 Computing the index of the reference block */
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/* 1.2.1 Taking pseudo-random value from the previous block */
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if (data_independent_addressing) {
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if (i % ARGON2_ADDRESSES_IN_BLOCK == 0) {
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next_addresses(&address_block, &input_block, &zero_block);
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}
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pseudo_rand = address_block.v[i % ARGON2_ADDRESSES_IN_BLOCK];
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} else {
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pseudo_rand = instance->memory[prev_offset].v[0];
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}
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/* 1.2.2 Computing the lane of the reference block */
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ref_lane = ((pseudo_rand >> 32)) % instance->lanes;
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if ((position.pass == 0) && (position.slice == 0)) {
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/* Can not reference other lanes yet */
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ref_lane = position.lane;
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}
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/* 1.2.3 Computing the number of possible reference block within the
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* lane.
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*/
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position.index = i;
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ref_index = index_alpha(instance, &position, pseudo_rand & 0xFFFFFFFF,
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ref_lane == position.lane);
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/* 2 Creating a new block */
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ref_block =
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instance->memory + instance->lane_length * ref_lane + ref_index;
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curr_block = instance->memory + curr_offset;
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if (ARGON2_VERSION_10 == instance->version) {
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/* version 1.2.1 and earlier: overwrite, not XOR */
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fill_block(instance->memory + prev_offset, ref_block, curr_block, 0);
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} else {
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if(0 == position.pass) {
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fill_block(instance->memory + prev_offset, ref_block,
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curr_block, 0);
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} else {
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fill_block(instance->memory + prev_offset, ref_block,
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curr_block, 1);
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}
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}
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}
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}
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