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[Cipher_code.git] / OneRoundIoT / openssl / openssl_evp_ebc.c

//gcc pixmap_io.c  -c
//gcc openssl_evp_ebc.c pixmap_io.o -o openssl_evp_ebc -I /usr/include/openssl/ -lcrypto -O3 -std=c99 


#include <openssl/conf.h>
#include <openssl/evp.h>
#include <openssl/err.h>
#include <openssl/ssl.h>
#include <openssl/bio.h>
#include <string.h>
#include <sys/time.h>
#include "pixmap_io.h"

typedef unsigned char   uchar;


double TimeStart()
{
  struct timeval tstart;
  gettimeofday(&tstart,0);
  return( (double) (tstart.tv_sec + tstart.tv_usec*1e-6) );
}

double TimeStop(double t)
{
  struct timeval tend;

  gettimeofday(&tend,0);
  t = (double) (tend.tv_sec + tend.tv_usec*1e-6) - t;
  return (t);
}


void handleErrors(void)
{
  ERR_print_errors_fp(stderr);
  abort();
}


int encrypt(unsigned char *plaintext, int plaintext_len, unsigned char *key,
  unsigned char *iv, unsigned char *ciphertext)
{
  EVP_CIPHER_CTX *ctx;

  int len;

  int ciphertext_len;

  /* Create and initialise the context */
  if(!(ctx = EVP_CIPHER_CTX_new())) handleErrors();

  /* Initialise the encryption operation. IMPORTANT - ensure you use a key
   * and IV size appropriate for your cipher
   * In this example we are using 256 bit AES (i.e. a 256 bit key). The
   * IV size for *most* modes is the same as the block size. For AES this
   * is 128 bits */

  //256
  //avant ecb
  if(1 != EVP_EncryptInit_ex(ctx, EVP_aes_128_ecb(), NULL, key, iv))
    handleErrors();

//  int cipherBlockSize = EVP_CIPHER_CTX_block_size(ctx);  
//  printf("INFO(evp_encrypt): block size: %d\n", cipherBlockSize);

  
  /* Provide the message to be encrypted, and obtain the encrypted output.
   * EVP_EncryptUpdate can be called multiple times if necessary
   */

  if(1 != EVP_EncryptUpdate(ctx, ciphertext, &len, plaintext, plaintext_len))
    handleErrors();
  ciphertext_len = len;

  




  
  /* Finalise the encryption. Further ciphertext bytes may be written at
   * this stage.
   */
  if(1 != EVP_EncryptFinal_ex(ctx, ciphertext + len, &len)) handleErrors();
  ciphertext_len += len;

  /* Clean up */
  EVP_CIPHER_CTX_free(ctx);

  return ciphertext_len;
}

int decrypt(unsigned char *ciphertext, int ciphertext_len, unsigned char *key,
  unsigned char *iv, unsigned char *plaintext)
{
  EVP_CIPHER_CTX *ctx;

  int len;

  int plaintext_len;

  /* Create and initialise the context */
  if(!(ctx = EVP_CIPHER_CTX_new())) handleErrors();

  /* Initialise the decryption operation. IMPORTANT - ensure you use a key
   * and IV size appropriate for your cipher
   * In this example we are using 256 bit AES (i.e. a 256 bit key). The
   * IV size for *most* modes is the same as the block size. For AES this
   * is 128 bits */

  //256

  //avant => ecb
  if(1 != EVP_DecryptInit_ex(ctx, EVP_aes_128_ecb(), NULL, key, iv))
    handleErrors();

  /* Provide the message to be decrypted, and obtain the plaintext output.
   * EVP_DecryptUpdate can be called multiple times if necessary
   */
  
 
  if(1 != EVP_DecryptUpdate(ctx, plaintext, &len, ciphertext, ciphertext_len))
    handleErrors();
  plaintext_len = len;

  /* Finalise the decryption. Further plaintext bytes may be written at
   * this stage.
   */
  if(1 != EVP_DecryptFinal_ex(ctx, plaintext + len, &len)) handleErrors();
  plaintext_len += len;

  /* Clean up */
  EVP_CIPHER_CTX_free(ctx);

  return plaintext_len;
}


int main (void)
{
  /* Set up the key and iv. Do I need to say to not hard code these in a
   * real application? :-)
   */

  /* A 256 bit key */
//  unsigned char *key = (unsigned char *)"01234567890123456789012345678901";
  unsigned char *key = (unsigned char *)"0123456789012345";
  
  /* A 128 bit IV */
  unsigned char *iv = (unsigned char *)"0123456789012345";

  /* Message to be encrypted */




  
  /* Buffer for ciphertext. Ensure the buffer is long enough for the
   * ciphertext which may be longer than the plaintext, dependant on the
   * algorithm and mode
   */

  int width;
  int height;
  uchar *data_R, *data_G, *data_B;
//  load_RGB_pixmap("lena.ppm", &width, &height, &data_R, &data_G, &data_B);


//  load_RGB_pixmap("No_ecb_mode_picture.ppm", &width, &height, &data_R, &data_G, &data_B);
  load_RGB_pixmap("4096.ppm", &width, &height, &data_R, &data_G, &data_B);
  int size=width*height*3;

  int oneD=width*height;
  uchar *plaintext = malloc(size);

  
  for(int i=0;i<oneD;i++) {
    plaintext[i]=data_R[i];
    plaintext[oneD+i]=data_G[i];
    plaintext[2*oneD+i]=data_B[i];
  }

  

  uchar *ciphertext = malloc(size);

  /* Buffer for the decrypted text */
  uchar *decryptedtext = malloc(size);

  int decryptedtext_len, ciphertext_len;

  /* Initialise the library */
  ERR_load_crypto_strings();
  OpenSSL_add_all_algorithms();
  OPENSSL_config(NULL);

  int ss=0;
   double time=0;
  double t=TimeStart();

  
  /* Encrypt the plaintext */


  int i;

  for(i=0;i<100;i++)
  {  
    ciphertext_len = encrypt (plaintext, size, key, iv,
                              ciphertext);
    ss+=ciphertext[100];
  }

 time+=TimeStop(t);

 printf("Time encrypt %f   ss %d\n",time,ss);


 for(int i=0;i<oneD;i++) {
    data_R[i]=ciphertext[i];
    data_G[i]=ciphertext[oneD+i];
    data_B[i]=ciphertext[2*oneD+i];
  }
  store_RGB_pixmap("lena2.ppm", data_R, data_G, data_B, width, height);            
 
  
  time=0;
  t=0;
  t=TimeStart();

  for(int i=0;i<100;i++)
  {  
    /* Decrypt the ciphertext */
    decryptedtext_len = decrypt(ciphertext, ciphertext_len, key, iv,
                                decryptedtext);
  }

 time+=TimeStop(t);

 printf("Time decrypt %f\n",time);


  for(int i=0;i<oneD;i++) {
    data_R[i]=decryptedtext[i];
    data_G[i]=decryptedtext[oneD+i];
    data_B[i]=decryptedtext[2*oneD+i];
  }
  store_RGB_pixmap("lena3.ppm", data_R, data_G, data_B, width, height);             

  

  /* Clean up */
  EVP_cleanup();
  ERR_free_strings();

  return 0;
}