};
static
-void memxor_P(void* d, PGM_VOID_P s, uint8_t length_B){
+void memxor_P(void *d, PGM_VOID_P s, uint8_t length_B){
while(length_B--){
*((uint8_t*)d) ^= pgm_read_byte(s);
d = (uint8_t*)d +1;
#define SHLX1(a) c0=((a)>>7); (a)^=(((a)<<1)|c1)
static
-void clock_r(uint8_t* r, uint8_t ibit, uint8_t cbit){
+void clock_r(uint8_t *r, uint8_t ibit, uint8_t cbit){
uint8_t i,c0=0,c1=0; /* carry */
ibit ^= ((r[159/8])>>(159%8))&1; /* ibit is now the same as feedback_bit */
if(cbit){
};
static
-void clock_s(uint8_t* s, uint8_t ibit, uint8_t cbit){
+void clock_s(uint8_t *s, uint8_t ibit, uint8_t cbit){
uint8_t s0[20], s1[20];
uint8_t i,c=0, c2=0;
ibit ^= (s[19])>>7;
}
static
-void clock_kg(uint8_t* r, uint8_t* s, uint8_t mixing, uint8_t input){
+void clock_kg(uint8_t *r, uint8_t *s, uint8_t mixing, uint8_t input){
uint8_t rb, sb;
rb = ((s[ 54/8])>>(( 54%8))) ^ ((r[106/8])>>(((106%8))));
sb = ((s[106/8])>>((106%8))) ^ ((r[ 53/8])>>((( 53%8))));
clock_s(s, input, sb);
}
-void mickey128_init(void* key, uint16_t keysize_b,
- void* iv, uint16_t ivsize_b,
- mickey128_ctx_t* ctx){
+void mickey128_init(void *key, uint16_t keysize_b,
+ void *iv, uint16_t ivsize_b,
+ mickey128_ctx_t *ctx){
uint16_t i;
memset(ctx->r, 0, 20);
memset(ctx->s, 0, 20);
}
}
-uint8_t mickey128_getbit(mickey128_ctx_t* ctx){
+uint8_t mickey128_getbit(mickey128_ctx_t *ctx){
uint8_t ret;
ret = 1&(*(ctx->r) ^ *(ctx->s));
clock_kg(ctx->r, ctx->s, 0, 0);
return ret;
}
-uint8_t mickey128_getbyte(mickey128_ctx_t* ctx){
+uint8_t mickey128_getbyte(mickey128_ctx_t *ctx){
uint8_t i,ret=0;
for(i=0; i<8; ++i){
ret<<=1;