GmSSL/crypto/zuc/zuc.c

#include <assert.h>
#include "../modes/modes_lcl.h"
#include "zuc.h"


static uint8_t S0[256] = {
	0x3e,0x72,0x5b,0x47,0xca,0xe0,0x00,0x33,0x04,0xd1,0x54,0x98,0x09,0xb9,0x6d,0xcb,
	0x7b,0x1b,0xf9,0x32,0xaf,0x9d,0x6a,0xa5,0xb8,0x2d,0xfc,0x1d,0x08,0x53,0x03,0x90,
	0x4d,0x4e,0x84,0x99,0xe4,0xce,0xd9,0x91,0xdd,0xb6,0x85,0x48,0x8b,0x29,0x6e,0xac,
	0xcd,0xc1,0xf8,0x1e,0x73,0x43,0x69,0xc6,0xb5,0xbd,0xfd,0x39,0x63,0x20,0xd4,0x38,
	0x76,0x7d,0xb2,0xa7,0xcf,0xed,0x57,0xc5,0xf3,0x2c,0xbb,0x14,0x21,0x06,0x55,0x9b,
	0xe3,0xef,0x5e,0x31,0x4f,0x7f,0x5a,0xa4,0x0d,0x82,0x51,0x49,0x5f,0xba,0x58,0x1c,
	0x4a,0x16,0xd5,0x17,0xa8,0x92,0x24,0x1f,0x8c,0xff,0xd8,0xae,0x2e,0x01,0xd3,0xad,
	0x3b,0x4b,0xda,0x46,0xeb,0xc9,0xde,0x9a,0x8f,0x87,0xd7,0x3a,0x80,0x6f,0x2f,0xc8,
	0xb1,0xb4,0x37,0xf7,0x0a,0x22,0x13,0x28,0x7c,0xcc,0x3c,0x89,0xc7,0xc3,0x96,0x56,
	0x07,0xbf,0x7e,0xf0,0x0b,0x2b,0x97,0x52,0x35,0x41,0x79,0x61,0xa6,0x4c,0x10,0xfe,
	0xbc,0x26,0x95,0x88,0x8a,0xb0,0xa3,0xfb,0xc0,0x18,0x94,0xf2,0xe1,0xe5,0xe9,0x5d,
	0xd0,0xdc,0x11,0x66,0x64,0x5c,0xec,0x59,0x42,0x75,0x12,0xf5,0x74,0x9c,0xaa,0x23,
	0x0e,0x86,0xab,0xbe,0x2a,0x02,0xe7,0x67,0xe6,0x44,0xa2,0x6c,0xc2,0x93,0x9f,0xf1,
	0xf6,0xfa,0x36,0xd2,0x50,0x68,0x9e,0x62,0x71,0x15,0x3d,0xd6,0x40,0xc4,0xe2,0x0f,
	0x8e,0x83,0x77,0x6b,0x25,0x05,0x3f,0x0c,0x30,0xea,0x70,0xb7,0xa1,0xe8,0xa9,0x65,
	0x8d,0x27,0x1a,0xdb,0x81,0xb3,0xa0,0xf4,0x45,0x7a,0x19,0xdf,0xee,0x78,0x34,0x60
}; 

static uint8_t S1[256] =  {
	0x55,0xc2,0x63,0x71,0x3b,0xc8,0x47,0x86,0x9f,0x3c,0xda,0x5b,0x29,0xaa,0xfd,0x77,
	0x8c,0xc5,0x94,0x0c,0xa6,0x1a,0x13,0x00,0xe3,0xa8,0x16,0x72,0x40,0xf9,0xf8,0x42,
	0x44,0x26,0x68,0x96,0x81,0xd9,0x45,0x3e,0x10,0x76,0xc6,0xa7,0x8b,0x39,0x43,0xe1,
	0x3a,0xb5,0x56,0x2a,0xc0,0x6d,0xb3,0x05,0x22,0x66,0xbf,0xdc,0x0b,0xfa,0x62,0x48,
	0xdd,0x20,0x11,0x06,0x36,0xc9,0xc1,0xcf,0xf6,0x27,0x52,0xbb,0x69,0xf5,0xd4,0x87,
	0x7f,0x84,0x4c,0xd2,0x9c,0x57,0xa4,0xbc,0x4f,0x9a,0xdf,0xfe,0xd6,0x8d,0x7a,0xeb,
	0x2b,0x53,0xd8,0x5c,0xa1,0x14,0x17,0xfb,0x23,0xd5,0x7d,0x30,0x67,0x73,0x08,0x09,
	0xee,0xb7,0x70,0x3f,0x61,0xb2,0x19,0x8e,0x4e,0xe5,0x4b,0x93,0x8f,0x5d,0xdb,0xa9,
	0xad,0xf1,0xae,0x2e,0xcb,0x0d,0xfc,0xf4,0x2d,0x46,0x6e,0x1d,0x97,0xe8,0xd1,0xe9,
	0x4d,0x37,0xa5,0x75,0x5e,0x83,0x9e,0xab,0x82,0x9d,0xb9,0x1c,0xe0,0xcd,0x49,0x89,
	0x01,0xb6,0xbd,0x58,0x24,0xa2,0x5f,0x38,0x78,0x99,0x15,0x90,0x50,0xb8,0x95,0xe4,
	0xd0,0x91,0xc7,0xce,0xed,0x0f,0xb4,0x6f,0xa0,0xcc,0xf0,0x02,0x4a,0x79,0xc3,0xde,
	0xa3,0xef,0xea,0x51,0xe6,0x6b,0x18,0xec,0x1b,0x2c,0x80,0xf7,0x74,0xe7,0xff,0x21,
	0x5a,0x6a,0x54,0x1e,0x41,0x31,0x92,0x35,0xc4,0x33,0x07,0x0a,0xba,0x7e,0x0e,0x34,
	0x88,0xb1,0x98,0x7c,0xf3,0x3d,0x60,0x6c,0x7b,0xca,0xd3,0x1f,0x32,0x65,0x04,0x28,
	0x64,0xbe,0x85,0x9b,0x2f,0x59,0x8a,0xd7,0xb0,0x25,0xac,0xaf,0x12,0x03,0xe2,0xf2
};

static uint32_t EK_d[16] = {
	0x44D7, 0x26BC, 0x626B, 0x135E, 0x5789, 0x35E2, 0x7135, 0x09AF,
	0x4D78, 0x2F13, 0x6BC4, 0x1AF1, 0x5E26, 0x3C4D, 0x789A, 0x47AC
};

static inline uint32_t AddM(uint32_t a, uint32_t b)
{
	uint32_t c = a + b;
	return (c & 0x7FFFFFFF) + (c >> 31);
}

#define MulByPow2(x, k) ((((x) << k) | ((x) >> (31 - k))) & 0x7FFFFFFF)

static void LFSRWithInitialisationMode(ZUC_KEY *key, uint32_t u)
{
	uint32_t f, v;
	f = key->LFSR_S0;
	
	v = MulByPow2(key->LFSR_S0, 8);
	f = AddM(f, v);
	v = MulByPow2(key->LFSR_S4, 20);
	f = AddM(f, v);
	v = MulByPow2(key->LFSR_S10, 21);
	f = AddM(f, v);
	v = MulByPow2(key->LFSR_S13, 17);
	f = AddM(f, v);
	v = MulByPow2(key->LFSR_S15, 15);
	f = AddM(f, v);
	
	f = AddM(f, u);
	
	/* update the state */
	key->LFSR_S0 = key->LFSR_S1;
	key->LFSR_S1 = key->LFSR_S2;
	key->LFSR_S2 = key->LFSR_S3;
	key->LFSR_S3 = key->LFSR_S4;
	key->LFSR_S4 = key->LFSR_S5;
	key->LFSR_S5 = key->LFSR_S6;
	key->LFSR_S6 = key->LFSR_S7;
	key->LFSR_S7 = key->LFSR_S8;
	key->LFSR_S8 = key->LFSR_S9;
	key->LFSR_S9 = key->LFSR_S10;
	key->LFSR_S10 = key->LFSR_S11;
	key->LFSR_S11 = key->LFSR_S12;
	key->LFSR_S12 = key->LFSR_S13;
	key->LFSR_S13 = key->LFSR_S14;
	key->LFSR_S14 = key->LFSR_S15;
	key->LFSR_S15 = f;
}

/* LFSR with work mode */
static void LFSRWithWorkMode(ZUC_KEY *key)
{
	uint32_t f, v;
	f = key->LFSR_S0;
	
	v = MulByPow2(key->LFSR_S0, 8);
	f = AddM(f, v);
	v = MulByPow2(key->LFSR_S4, 20);
	f = AddM(f, v);
	v = MulByPow2(key->LFSR_S10, 21);
	f = AddM(f, v);
	v = MulByPow2(key->LFSR_S13, 17);
	f = AddM(f, v);
	v = MulByPow2(key->LFSR_S15, 15);
	f = AddM(f, v);
	
	/* update the state */
	key->LFSR_S0 = key->LFSR_S1;
	key->LFSR_S1 = key->LFSR_S2;
	key->LFSR_S2 = key->LFSR_S3;
	key->LFSR_S3 = key->LFSR_S4;
	key->LFSR_S4 = key->LFSR_S5;
	key->LFSR_S5 = key->LFSR_S6;
	key->LFSR_S6 = key->LFSR_S7;
	key->LFSR_S7 = key->LFSR_S8;
	key->LFSR_S8 = key->LFSR_S9;
	key->LFSR_S9 = key->LFSR_S10;
	key->LFSR_S10 = key->LFSR_S11;
	key->LFSR_S11 = key->LFSR_S12;
	key->LFSR_S12 = key->LFSR_S13;
	key->LFSR_S13 = key->LFSR_S14;
	key->LFSR_S14 = key->LFSR_S15;
	key->LFSR_S15 = f;
}

/* BitReorganization */
static inline void BitReorganization(ZUC_KEY *key)
{
	key->BRC_X0 = ((key->LFSR_S15 & 0x7FFF8000) << 1) | (key->LFSR_S14 & 0xFFFF);
	key->BRC_X1 = ((key->LFSR_S11 & 0xFFFF) << 16) | (key->LFSR_S9 >> 15);
	key->BRC_X2 = ((key->LFSR_S7 & 0xFFFF) << 16) | (key->LFSR_S5 >> 15);
	key->BRC_X3 = ((key->LFSR_S2 & 0xFFFF) << 16) | (key->LFSR_S0 >> 15);
}

#define ROT(a, k) (((a) << k) | ((a) >> (32 - k)))

static inline uint32_t L1(uint32_t X)
{
	return (X ^ ROT(X, 2) ^ ROT(X, 10) ^ ROT(X, 18) ^ ROT(X, 24));
}

static inline uint32_t L2(uint32_t X)
{
	return (X ^ ROT(X, 8) ^ ROT(X, 14) ^ ROT(X, 22) ^ ROT(X, 30));
}

#define MAKEuint32_t(a, b, c, d) (((uint32_t)(a) << 24) | ((uint32_t)(b) << 16) | ((uint32_t)(c) << 8) | ((uint32_t)(d)))

static uint32_t F(ZUC_KEY *key)
{
	uint32_t W, W1, W2, u, v;
	
	W  = (key->BRC_X0 ^ key->F_R1) + key->F_R2;
	W1 = key->F_R1 + key->BRC_X1;
	W2 = key->F_R2 ^ key->BRC_X2;
	
	u = L1((W1 << 16) | (W2 >> 16));
	v = L2((W2 << 16) | (W1 >> 16));
	
	key->F_R1 = MAKEuint32_t(S0[u >> 24], S1[(u >> 16) & 0xFF], S0[(u >> 8) & 0xFF], S1[u & 0xFF]);
	key->F_R2 = MAKEuint32_t(S0[v >> 24], S1[(v >> 16) & 0xFF], S0[(v >> 8) & 0xFF], S1[v & 0xFF]);
	
	return W;
}

#define MAKEU31(a, b, c) (((uint32_t)(a) << 23) | ((uint32_t)(b) << 8) | (uint32_t)(c))

void ZUC_set_key(ZUC_KEY *key, const unsigned char *k, const unsigned char *iv)
{
	uint32_t w, nCount;

	key->LFSR_S0 = MAKEU31(k[0], EK_d[0], iv[0]);
	key->LFSR_S1 = MAKEU31(k[1], EK_d[1], iv[1]);
	key->LFSR_S2 = MAKEU31(k[2], EK_d[2], iv[2]);
	key->LFSR_S3 = MAKEU31(k[3], EK_d[3], iv[3]);
	key->LFSR_S4 = MAKEU31(k[4], EK_d[4], iv[4]);
	key->LFSR_S5 = MAKEU31(k[5], EK_d[5], iv[5]);
	key->LFSR_S6 = MAKEU31(k[6], EK_d[6], iv[6]);
	key->LFSR_S7 = MAKEU31(k[7], EK_d[7], iv[7]);
	key->LFSR_S8 = MAKEU31(k[8], EK_d[8], iv[8]);
	key->LFSR_S9 = MAKEU31(k[9], EK_d[9], iv[9]);
	key->LFSR_S10 = MAKEU31(k[10], EK_d[10], iv[10]);
	key->LFSR_S11 = MAKEU31(k[11], EK_d[11], iv[11]);
	key->LFSR_S12 = MAKEU31(k[12], EK_d[12], iv[12]);
	key->LFSR_S13 = MAKEU31(k[13], EK_d[13], iv[13]);
	key->LFSR_S14 = MAKEU31(k[14], EK_d[14], iv[14]);
	key->LFSR_S15 = MAKEU31(k[15], EK_d[15], iv[15]);

	key->F_R1 = 0;
	key->F_R2 = 0;
	nCount = 32;

	while (nCount > 0) {
		BitReorganization(key);
		w = F(key);
		LFSRWithInitialisationMode(key, w >> 1);
		nCount--;
	}

	BitReorganization(key);
	F(key);
	LFSRWithWorkMode(key);

}

void ZUC_encrypt(ZUC_KEY *key, size_t inlen, const unsigned char *in, unsigned char *out)
{
	uint32_t word;
	int n = key->buf_index;

	assert(n < 4);

	while (n && inlen) {
		*(out++) = *(in++) ^ key->buf[n];
		n = (n + 1) % 4;
		inlen--;
	}
	
	while (inlen >= 4) {
		BitReorganization(key);
		word = GETU32(in);
		word ^= F(key) ^ key->BRC_X3;
		PUTU32(out, word);
		LFSRWithWorkMode(key);
		inlen -= 4;
		in += 4;
		out += 4;
	}

	if (inlen) {
		BitReorganization(key);
		word = F(key) ^ key->BRC_X3;
		LFSRWithWorkMode(key);
		PUTU32(key->buf, word);
		while (inlen-- > 0) {
			out[n] = in[n] ^ key->buf[n];
			n++;
		}
	}

	key->buf_index = n;
	return;
}