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/**
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* Implementation of the Lyra2 Password Hashing Scheme (PHS).
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*
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* Author: The Lyra PHC team (http://www.lyra-kdf.net/) -- 2014.
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*
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* This software is hereby placed in the public domain.
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*
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* THIS SOFTWARE IS PROVIDED BY THE AUTHORS ''AS IS'' AND ANY EXPRESS
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* OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
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* WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
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* ARE DISCLAIMED. IN NO EVENT SHALL THE AUTHORS OR CONTRIBUTORS BE
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* LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
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* CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
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* SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR
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* BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY,
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* WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE
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* OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE,
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* EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
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*/
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#include <stdio.h>
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#include <stdlib.h>
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#include <string.h>
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#include <time.h>
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#include "lyra2.h"
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#include "sponge.h"
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/**
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* Executes Lyra2 based on the G function from Blake2b. This version supports salts and passwords
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* whose combined length is smaller than the size of the memory matrix, (i.e., (nRows x nCols x b) bits,
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* where "b" is the underlying sponge's bitrate). In this implementation, the "basil" is composed by all
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* integer parameters (treated as type "unsigned int") in the order they are provided, plus the value
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* of nCols, (i.e., basil = kLen || pwdlen || saltlen || timeCost || nRows || nCols).
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*
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* @param K The derived key to be output by the algorithm
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* @param kLen Desired key length
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* @param pwd User password
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* @param pwdlen Password length
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* @param salt Salt
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* @param saltlen Salt length
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* @param timeCost Parameter to determine the processing time (T)
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* @param nRows Number or rows of the memory matrix (R)
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* @param nCols Number of columns of the memory matrix (C)
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*
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* @return 0 if the key is generated correctly; -1 if there is an error (usually due to lack of memory for allocation)
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*/
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int LYRA2(void *K, uint64_t kLen, const void *pwd, uint64_t pwdlen, const void *salt, uint64_t saltlen, uint64_t timeCost, uint64_t nRows, uint64_t nCols) {
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//============================= Basic variables ============================//
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int64_t row = 2; //index of row to be processed
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int64_t prev = 1; //index of prev (last row ever computed/modified)
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int64_t rowa = 0; //index of row* (a previous row, deterministically picked during Setup and randomly picked while Wandering)
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int64_t tau; //Time Loop iterator
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int64_t step = 1; //Visitation step (used during Setup and Wandering phases)
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int64_t window = 2; //Visitation window (used to define which rows can be revisited during Setup)
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int64_t gap = 1; //Modifier to the step, assuming the values 1 or -1
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int64_t i; //auxiliary iteration counter
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//==========================================================================/
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//========== Initializing the Memory Matrix and pointers to it =============//
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//Tries to allocate enough space for the whole memory matrix
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const int64_t ROW_LEN_INT64 = BLOCK_LEN_INT64 * nCols;
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const int64_t ROW_LEN_BYTES = ROW_LEN_INT64 * 8;
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i = (int64_t) ((int64_t) nRows * (int64_t) ROW_LEN_BYTES);
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uint64_t *wholeMatrix = malloc(i);
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if (wholeMatrix == NULL) {
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return -1;
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}
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memset(wholeMatrix, 0, i);
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//Allocates pointers to each row of the matrix
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uint64_t **memMatrix = malloc(nRows * sizeof (uint64_t*));
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if (memMatrix == NULL) {
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return -1;
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}
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//Places the pointers in the correct positions
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uint64_t *ptrWord = wholeMatrix;
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for (i = 0; i < nRows; i++) {
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memMatrix[i] = ptrWord;
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ptrWord += ROW_LEN_INT64;
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}
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//==========================================================================/
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//============= Getting the password + salt + basil padded with 10*1 ===============//
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//OBS.:The memory matrix will temporarily hold the password: not for saving memory,
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//but this ensures that the password copied locally will be overwritten as soon as possible
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//First, we clean enough blocks for the password, salt, basil and padding
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uint64_t nBlocksInput = ((saltlen + pwdlen + 6 * sizeof (uint64_t)) / BLOCK_LEN_BLAKE2_SAFE_BYTES) + 1;
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byte *ptrByte = (byte*) wholeMatrix;
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memset(ptrByte, 0, nBlocksInput * BLOCK_LEN_BLAKE2_SAFE_BYTES);
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//Prepends the password
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memcpy(ptrByte, pwd, pwdlen);
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ptrByte += pwdlen;
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//Concatenates the salt
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memcpy(ptrByte, salt, saltlen);
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ptrByte += saltlen;
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//Concatenates the basil: every integer passed as parameter, in the order they are provided by the interface
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memcpy(ptrByte, &kLen, sizeof (uint64_t));
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ptrByte += sizeof (uint64_t);
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memcpy(ptrByte, &pwdlen, sizeof (uint64_t));
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ptrByte += sizeof (uint64_t);
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memcpy(ptrByte, &saltlen, sizeof (uint64_t));
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ptrByte += sizeof (uint64_t);
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memcpy(ptrByte, &timeCost, sizeof (uint64_t));
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ptrByte += sizeof (uint64_t);
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memcpy(ptrByte, &nRows, sizeof (uint64_t));
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ptrByte += sizeof (uint64_t);
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memcpy(ptrByte, &nCols, sizeof (uint64_t));
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ptrByte += sizeof (uint64_t);
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//Now comes the padding
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*ptrByte = 0x80; //first byte of padding: right after the password
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ptrByte = (byte*) wholeMatrix; //resets the pointer to the start of the memory matrix
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ptrByte += nBlocksInput * BLOCK_LEN_BLAKE2_SAFE_BYTES - 1; //sets the pointer to the correct position: end of incomplete block
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*ptrByte ^= 0x01; //last byte of padding: at the end of the last incomplete block
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//==========================================================================/
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//======================= Initializing the Sponge State ====================//
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//Sponge state: 16 uint64_t, BLOCK_LEN_INT64 words of them for the bitrate (b) and the remainder for the capacity (c)
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uint64_t *state = malloc(16 * sizeof (uint64_t));
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if (state == NULL) {
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return -1;
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}
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initState(state);
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//==========================================================================/
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//================================ Setup Phase =============================//
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//Absorbing salt, password and basil: this is the only place in which the block length is hard-coded to 512 bits
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ptrWord = wholeMatrix;
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for (i = 0; i < nBlocksInput; i++) {
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absorbBlockBlake2Safe(state, ptrWord); //absorbs each block of pad(pwd || salt || basil)
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ptrWord += BLOCK_LEN_BLAKE2_SAFE_INT64; //goes to next block of pad(pwd || salt || basil)
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}
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//Initializes M[0] and M[1]
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reducedSqueezeRow0(state, memMatrix[0], nCols); //The locally copied password is most likely overwritten here
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reducedDuplexRow1(state, memMatrix[0], memMatrix[1], nCols);
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do {
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//M[row] = rand; //M[row*] = M[row*] XOR rotW(rand)
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reducedDuplexRowSetup(state, memMatrix[prev], memMatrix[rowa], memMatrix[row], nCols);
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//updates the value of row* (deterministically picked during Setup))
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rowa = (rowa + step) & (window - 1);
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//update prev: it now points to the last row ever computed
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prev = row;
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//updates row: goes to the next row to be computed
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row++;
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//Checks if all rows in the window where visited.
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if (rowa == 0) {
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step = window + gap; //changes the step: approximately doubles its value
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window *= 2; //doubles the size of the re-visitation window
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gap = -gap; //inverts the modifier to the step
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}
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} while (row < nRows);
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//==========================================================================/
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//============================ Wandering Phase =============================//
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row = 0; //Resets the visitation to the first row of the memory matrix
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for (tau = 1; tau <= timeCost; tau++) {
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//Step is approximately half the number of all rows of the memory matrix for an odd tau; otherwise, it is -1
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step = (tau % 2 == 0) ? -1 : nRows / 2 - 1;
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do {
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//Selects a pseudorandom index row*
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//------------------------------------------------------------------------------------------
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//rowa = ((unsigned int)state[0]) & (nRows-1); //(USE THIS IF nRows IS A POWER OF 2)
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rowa = ((uint64_t) (state[0])) % nRows; //(USE THIS FOR THE "GENERIC" CASE)
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//------------------------------------------------------------------------------------------
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//Performs a reduced-round duplexing operation over M[row*] XOR M[prev], updating both M[row*] and M[row]
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reducedDuplexRow(state, memMatrix[prev], memMatrix[rowa], memMatrix[row], nCols);
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//update prev: it now points to the last row ever computed
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prev = row;
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//updates row: goes to the next row to be computed
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//------------------------------------------------------------------------------------------
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//row = (row + step) & (nRows-1); //(USE THIS IF nRows IS A POWER OF 2)
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row = (row + step) % nRows; //(USE THIS FOR THE "GENERIC" CASE)
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//------------------------------------------------------------------------------------------
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} while (row != 0);
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}
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//==========================================================================/
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//============================ Wrap-up Phase ===============================//
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//Absorbs the last block of the memory matrix
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absorbBlock(state, memMatrix[rowa]);
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//Squeezes the key
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squeeze(state, K, kLen);
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//==========================================================================/
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//========================= Freeing the memory =============================//
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free(memMatrix);
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free(wholeMatrix);
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//Wiping out the sponge's internal state before freeing it
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memset(state, 0, 16 * sizeof (uint64_t));
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free(state);
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//==========================================================================/
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return 0;
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}
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