X-Git-Url: https://bilbo.iut-bm.univ-fcomte.fr/and/gitweb/Cipher_code.git/blobdiff_plain/121b99635da1e62a424bea25d9d54fb0845cba43..50cc69e2c323701acf1102861274d3ab3a54b002:/OneRoundIoT/OneRound/rc4_hash3.cpp

diff --git a/OneRoundIoT/OneRound/rc4_hash3.cpp b/OneRoundIoT/OneRound/rc4_hash3.cpp
index 5c9061c..3cb1e07 100644
--- a/OneRoundIoT/OneRound/rc4_hash3.cpp
+++ b/OneRoundIoT/OneRound/rc4_hash3.cpp
@@ -138,7 +138,7 @@ void prga(uchar *sc, uchar *X, int ldata, uchar *r, int h) {
 inline uchar  circ(uchar x,int n) {return (x << n) | (x >> (8 - n));}
 
 
-uint64_t xorshift64( const uint64_t state)
+inline static uint64_t xorshift64( const uint64_t state)
 {
   uint64_t x = state;
   x^= x << 13;
@@ -146,17 +146,9 @@ uint64_t xorshift64( const uint64_t state)
   x^= x << 17;
   return x;
 }
-uint xorshift32(const uint t)
-{
-  /* Algorithm "xor" from p. 4 of Marsaglia, "Xorshift RNGs" */
-  uint x = t;
-  x ^= x << 13;
-  x ^= x >> 17;
-  x ^= x << 5;
-  return x;
-}
 
-static inline uint64_t splitmix64(uint64_t index) {
+
+inline static  uint64_t splitmix64(uint64_t index) {
   uint64_t z = (index + UINT64_C(0x9E3779B97F4A7C15));
   z = (z ^ (z >> 30)) * UINT64_C(0xBF58476D1CE4E5B9);
   z = (z ^ (z >> 27)) * UINT64_C(0x94D049BB133111EB);
@@ -171,54 +163,20 @@ static inline uint64_t splitmix64(uint64_t index) {
 
 //the proposed hash function, which is based on DSD structure. Sensitivity is ensured by employing the binary diffusion
 
-void hash_DSD_BIN(uchar* seq_in, uchar* RM1,int len, uchar *S, int h) {
-
-
-  // Goal: Calculate the hash value
-  // Output: RM (hash value)
-
-//  uchar *X=new uchar[h2];
-//  uchar *fX=new uchar[h2];
-  uchar X[h];
-  int ind1,ind2;
-
-
-  uint32_t *rm=(uint32_t*)RM1;
-  uint32_t *xx=(uint32_t*)X;
-  uint32_t *ss=(uint32_t*)seq_in;
+void hash_DSD_BIN(uint64_t * ss, uint64_t* rm,int len,int h) {
 
 
+  int ind1=0;
   
   for(int it=0;it<len;it++) {
-    //ind1=Pbox[it]*h;
-    //ind2=Pbox[(it+len/2)]*h;
-
-    ind1=it*h/4;
-    // Mix with dynamic RM
-    uint64_t sum=0;
-    /*     for(int a=0;a<h;a+=4) {
-       X[a]=RM1[a]^seq_in[ind1+a];
-       X[a+1]=RM1[a+1]^seq_in[ind1+a+1];
-       X[a+2]=RM1[a+2]^seq_in[ind1+a+2];
-       X[a+3]=RM1[a+3]^seq_in[ind1+a+3];
-     }
-    */
-
-    
-     for(int a=0;a<h/4;a++) {
-       xx[a]=rm[a]^ss[ind1+a];
-       sum+=xx[a];
-     }
-
-
-
-
-     rm[0]=xorshift32(sum);
-     for(int a=1;a<h/4;a++) {
-       rm[a]^=xorshift32(rm[a-1]);
-     }
-
+    rm[0]=rm[h-1]^ss[ind1];
+    rm[0]=xorshift64(rm[0] );
+    for(int a=1;a<h;a++) {
+      rm[a]=rm[a-1]^ss[ind1+a];
+      rm[a]=xorshift64(rm[a]);
+    }
 
+    ind1+=h;
   }
 
  
@@ -317,10 +275,12 @@ int main(int argc, char** argv) {
   if(change==1) {
     
     seq[4]++;
+    //    seq[5]--;
   }
   if(change==2) {
     
     seq[9]++;
+    //   seq[10]--;
   }
 
   printf("seq 4 %d\n",seq[4]);
@@ -393,10 +353,15 @@ int main(int argc, char** argv) {
 
   
   time=0;
+  uint64_t *rm=(uint64_t*)RM1;
+  uint64_t *ss=(uint64_t*)seq;
+
+
+
   t=TimeStart();
   for(int i=0;i<nb_test;i++)
   {
-    hash_DSD_BIN(seq, RM1,len,Sbox1,h);
+    hash_DSD_BIN(ss, rm,len,h>>3);
   }