import java.util.Arrays; public class zuc256 { // S盒定义 private static final int[] S0 = { 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 }; private static final int[] S1 = { 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 }; // 常量数组D private static final int[][] ZUC256_D = { {0x22,0x2F,0x24,0x2A,0x6D,0x40,0x40,0x40,0x40,0x40,0x40,0x40,0x40,0x52,0x10,0x30}, {0x22,0x2F,0x25,0x2A,0x6D,0x40,0x40,0x40,0x40,0x40,0x40,0x40,0x40,0x52,0x10,0x30}, {0x23,0x2F,0x24,0x2A,0x6D,0x40,0x40,0x40,0x40,0x40,0x40,0x40,0x40,0x52,0x10,0x30}, {0x23,0x2F,0x25,0x2A,0x6D,0x40,0x40,0x40,0x40,0x40,0x40,0x40,0x40,0x52,0x10,0x30} }; // ZUC状态类 public static class ZUCState { int[] LFSR = new int[16]; // 线性反馈移位寄存器 int R1; // 寄存器1 int R2; // 寄存器2 } // 加密上下文类 public static class ZUC256EncryptCtx { ZUCState state = new ZUCState(); byte[] buf = new byte[4]; int buflen; } // MAC上下文类 public static class ZUC256MacCtx { int[] LFSR = new int[16]; int R1; int R2; byte[] buf = new byte[4]; int buflen; int[] T = new int[4]; int[] K0 = new int[4]; int macbits; } // 辅助方法:将字节数组转换为32位整数 private static int getU32(byte[] p, int offset) { return ((p[offset] & 0xFF) << 24) | ((p[offset + 1] & 0xFF) << 16) | ((p[offset + 2] & 0xFF) << 8) | (p[offset + 3] & 0xFF); } // 辅助方法:将32位整数转换为字节数组 private static void putU32(byte[] p, int offset, int v) { p[offset] = (byte) (v >> 24); p[offset + 1] = (byte) (v >> 16); p[offset + 2] = (byte) (v >> 8); p[offset + 3] = (byte) v; } // 31位加法 private static int add31(int a, int b) { long sum = (long)a + b; return (int) ((sum & 0x7FFFFFFF) + (sum >> 31)); } // 31位旋转 private static int rot31(int a, int k) { return ((a << k) | (a >>> (31 - k))) & 0x7FFFFFFF; } // 32位旋转 private static int rot32(int a, int k) { return (a << k) | (a >>> (32 - k)); } // L1函数 private static int L1(int x) { return x ^ rot32(x, 2) ^ rot32(x, 10) ^ rot32(x, 18) ^ rot32(x, 24); } // L2函数 private static int L2(int x) { return x ^ rot32(x, 8) ^ rot32(x, 14) ^ rot32(x, 22) ^ rot32(x, 30); } // 初始化MAC密钥 private static void zuc256SetMacKey(ZUCState key, byte[] K, byte[] IV, int macbits) { int[] LFSR = key.LFSR; int R1 = 0; int R2 = 0; int X0, X1, X2; int W, W1, W2, U, V; int[] D; int IV17 = (IV[17] & 0xFF) >> 2; int IV18 = ((IV[17] & 0x03) << 4) | ((IV[18] & 0xFF) >> 4); int IV19 = ((IV[18] & 0x0F) << 2) | ((IV[19] & 0xFF) >> 6); int IV20 = IV[19] & 0x3F; int IV21 = (IV[20] & 0xFF) >> 2; int IV22 = ((IV[20] & 0x03) << 4) | ((IV[21] & 0xFF) >> 4); int IV23 = ((IV[21] & 0x0F) << 2) | ((IV[22] & 0xFF) >> 6); int IV24 = IV[22] & 0x3F; D = (macbits / 32 < 3) ? ZUC256_D[macbits / 32] : ZUC256_D[3]; LFSR[0] = makeU31(K[0] & 0xFF, D[0], K[21] & 0xFF, K[16] & 0xFF); LFSR[1] = makeU31(K[1] & 0xFF, D[1], K[22] & 0xFF, K[17] & 0xFF); LFSR[2] = makeU31(K[2] & 0xFF, D[2], K[23] & 0xFF, K[18] & 0xFF); LFSR[3] = makeU31(K[3] & 0xFF, D[3], K[24] & 0xFF, K[19] & 0xFF); LFSR[4] = makeU31(K[4] & 0xFF, D[4], K[25] & 0xFF, K[20] & 0xFF); LFSR[5] = makeU31(IV[0] & 0xFF, (D[5] | IV17), K[5] & 0xFF, K[26] & 0xFF); LFSR[6] = makeU31(IV[1] & 0xFF, (D[6] | IV18), K[6] & 0xFF, K[27] & 0xFF); LFSR[7] = makeU31(IV[10] & 0xFF, (D[7] | IV19), K[7] & 0xFF, IV[2] & 0xFF); LFSR[8] = makeU31(K[8] & 0xFF, (D[8] | IV20), IV[3] & 0xFF, IV[11] & 0xFF); LFSR[9] = makeU31(K[9] & 0xFF, (D[9] | IV21), IV[12] & 0xFF, IV[4] & 0xFF); LFSR[10] = makeU31(IV[5] & 0xFF, (D[10] | IV22), K[10] & 0xFF, K[28] & 0xFF); LFSR[11] = makeU31(K[11] & 0xFF, (D[11] | IV23), IV[6] & 0xFF, IV[13] & 0xFF); LFSR[12] = makeU31(K[12] & 0xFF, (D[12] | IV24), IV[7] & 0xFF, IV[14] & 0xFF); LFSR[13] = makeU31(K[13] & 0xFF, D[13], IV[15] & 0xFF, IV[8] & 0xFF); LFSR[14] = makeU31(K[14] & 0xFF, (D[14] | (K[31] >>> 4)), IV[16] & 0xFF, IV[9] & 0xFF); LFSR[15] = makeU31(K[15] & 0xFF, (D[15] | (K[31] & 0x0F)), K[30] & 0xFF, K[29] & 0xFF); for (int i = 0; i < 32; i++) { // BitReconstruction3 X0 = ((LFSR[15] & 0x7FFF8000) << 1) | (LFSR[14] & 0xFFFF); X1 = ((LFSR[11] & 0xFFFF) << 16) | (LFSR[9] >>> 15); X2 = ((LFSR[7] & 0xFFFF) << 16) | (LFSR[5] >>> 15); // F(X0, X1, X2) W = (X0 ^ R1) + R2; W1 = R1 + X1; W2 = R2 ^ X2; U = L1((W1 << 16) | (W2 >>> 16)); V = L2((W2 << 16) | (W1 >>> 16)); R1 = makeU32(S0[(U >>> 24) & 0xFF], S1[(U >>> 16) & 0xFF], S0[(U >>> 8) & 0xFF], S1[U & 0xFF]); R2 = makeU32(S0[(V >>> 24) & 0xFF], S1[(V >>> 16) & 0xFF], S0[(V >>> 8) & 0xFF], S1[V & 0xFF]); // LFSRWithInitialisationMode(W >> 1) int v = LFSR[0]; v = add31(v, rot31(LFSR[0], 8)); v = add31(v, rot31(LFSR[4], 20)); v = add31(v, rot31(LFSR[10], 21)); v = add31(v, rot31(LFSR[13], 17)); v = add31(v, rot31(LFSR[15], 15)); v = add31(v, W >>> 1); System.arraycopy(LFSR, 1, LFSR, 0, 15); LFSR[15] = v; } // BitReconstruction2 X1 = ((LFSR[11] & 0xFFFF) << 16) | (LFSR[9] >>> 15); X2 = ((LFSR[7] & 0xFFFF) << 16) | (LFSR[5] >>> 15); // F_(X1, X2) W1 = R1 + X1; W2 = R2 ^ X2; U = L1((W1 << 16) | (W2 >>> 16)); V = L2((W2 << 16) | (W1 >>> 16)); R1 = makeU32(S0[(U >>> 24) & 0xFF], S1[(U >>> 16) & 0xFF], S0[(U >>> 8) & 0xFF], S1[U & 0xFF]); R2 = makeU32(S0[(V >>> 24) & 0xFF], S1[(V >>> 16) & 0xFF], S0[(V >>> 8) & 0xFF], S1[V & 0xFF]); // LFSRWithWorkMode long a = LFSR[0]; a += (long)LFSR[0] << 8; a += (long)LFSR[4] << 20; a += (long)LFSR[10] << 21; a += (long)LFSR[13] << 17; a += (long)LFSR[15] << 15; a = (a & 0x7FFFFFFF) + (a >>> 31); int v = (int) ((a & 0x7FFFFFFF) + (a >>> 31)); System.arraycopy(LFSR, 1, LFSR, 0, 15); LFSR[15] = v; key.R1 = R1; key.R2 = R2; } // 创建31位无符号整数 private static int makeU31(int a, int b, int c, int d) { return (((a & 0xFF) << 23) | ((b & 0xFF) << 16) | ((c & 0xFF) << 8) | (d & 0xFF)) & 0x7FFFFFFF; } // 创建32位无符号整数 private static int makeU32(int a, int b, int c, int d) { return ((a & 0xFF) << 24) | ((b & 0xFF) << 16) | ((c & 0xFF) << 8) | (d & 0xFF); } // 初始化ZUC256状态 public static void zuc256Init(ZUCState state, byte[] K, byte[] IV) { zuc256SetMacKey(state, K, IV, 0); } // 生成单个密钥字 public static int zuc256GenerateKeyword(ZUCState state) { int[] LFSR = state.LFSR; int R1 = state.R1; int R2 = state.R2; int X0, X1, X2, X3; int W1, W2, U, V; int Z; // BitReconstruction4 X0 = ((LFSR[15] & 0x7FFF8000) << 1) | (LFSR[14] & 0xFFFF); X1 = ((LFSR[11] & 0xFFFF) << 16) | (LFSR[9] >>> 15); X2 = ((LFSR[7] & 0xFFFF) << 16) | (LFSR[5] >>> 15); X3 = ((LFSR[2] & 0xFFFF) << 16) | (LFSR[0] >>> 15); Z = X3 ^ ((X0 ^ R1) + R2); // F_(X1, X2) W1 = R1 + X1; W2 = R2 ^ X2; U = L1((W1 << 16) | (W2 >>> 16)); V = L2((W2 << 16) | (W1 >>> 16)); R1 = makeU32(S0[(U >>> 24) & 0xFF], S1[(U >>> 16) & 0xFF], S0[(U >>> 8) & 0xFF], S1[U & 0xFF]); R2 = makeU32(S0[(V >>> 24) & 0xFF], S1[(V >>> 16) & 0xFF], S0[(V >>> 8) & 0xFF], S1[V & 0xFF]); // LFSRWithWorkMode long a = LFSR[0]; a += (long)LFSR[0] << 8; a += (long)LFSR[4] << 20; a += (long)LFSR[10] << 21; a += (long)LFSR[13] << 17; a += (long)LFSR[15] << 15; a = (a & 0x7FFFFFFF) + (a >>> 31); int v = (int) ((a & 0x7FFFFFFF) + (a >>> 31)); System.arraycopy(LFSR, 1, LFSR, 0, 15); LFSR[15] = v; state.R1 = R1; state.R2 = R2; return Z; } // 生成指定长度的密钥流 public static void zuc256GenerateKeystream(ZUCState state, int nwords, int[] keystream) { int[] LFSR = state.LFSR; int R1 = state.R1; int R2 = state.R2; int X0, X1, X2, X3; int W1, W2, U, V; for (int i = 0; i < nwords; i++) { // BitReconstruction4 X0 = ((LFSR[15] & 0x7FFF8000) << 1) | (LFSR[14] & 0xFFFF); X1 = ((LFSR[11] & 0xFFFF) << 16) | (LFSR[9] >>> 15); X2 = ((LFSR[7] & 0xFFFF) << 16) | (LFSR[5] >>> 15); X3 = ((LFSR[2] & 0xFFFF) << 16) | (LFSR[0] >>> 15); keystream[i] = X3 ^ ((X0 ^ R1) + R2); // F_(X1, X2) W1 = R1 + X1; W2 = R2 ^ X2; U = L1((W1 << 16) | (W2 >>> 16)); V = L2((W2 << 16) | (W1 >>> 16)); // S盒查找 int T0 = S0[(U >>> 24) & 0xFF] & 0xFF; int T2 = S0[(U >>> 8) & 0xFF] & 0xFF; int T4 = S0[(V >>> 24) & 0xFF] & 0xFF; int T6 = S0[(V >>> 8) & 0xFF] & 0xFF; int T1 = S1[(U >>> 16) & 0xFF] & 0xFF; int T3 = S1[U & 0xFF] & 0xFF; int T5 = S1[(V >>> 16) & 0xFF] & 0xFF; int T7 = S1[V & 0xFF] & 0xFF; R1 = makeU32(T0, T1, T2, T3); R2 = makeU32(T4, T5, T6, T7); // LFSRWithWorkMode long a = LFSR[0]; a += (long)LFSR[0] << 8; a += (long)LFSR[4] << 20; a += (long)LFSR[10] << 21; a += (long)LFSR[13] << 17; a += (long)LFSR[15] << 15; a = (a & 0x7FFFFFFF) + (a >>> 31); int v = (int) ((a & 0x7FFFFFFF) + (a >>> 31)); System.arraycopy(LFSR, 1, LFSR, 0, 15); LFSR[15] = v; } state.R1 = R1; state.R2 = R2; } // 初始化加密上下文 public static void zuc256EncryptInit(ZUC256EncryptCtx ctx, byte[] K, byte[] IV) { Arrays.fill(ctx.buf, (byte) 0); ctx.buflen = 0; zuc256Init(ctx.state, K, IV); } // 分阶段处理加密数据 public static void zuc256EncryptUpdate(ZUC256EncryptCtx ctx, byte[] in, int inlen, byte[] out) { if (in == null || out == null || inlen == 0) return; // 处理缓冲区中剩余的非4字节数据 if (ctx.buflen > 0) { int need = 4 - ctx.buflen; int copy = Math.min(inlen, need); System.arraycopy(in, 0, ctx.buf, ctx.buflen, copy); ctx.buflen += copy; // 调整输入指针和长度 byte[] newIn = new byte[inlen - copy]; if (inlen - copy > 0) { System.arraycopy(in, copy, newIn, 0, inlen - copy); } in = newIn; inlen -= copy; // 缓冲区已满,处理一个完整的4字节块 if (ctx.buflen == 4) { int keystream = zuc256GenerateKeyword(ctx.state); int plain = getU32(ctx.buf, 0); putU32(out, 0, plain ^ keystream); ctx.buflen = 0; Arrays.fill(ctx.buf, (byte) 0); // 调整输出指针 byte[] newOut = new byte[out.length - 4]; if (out.length - 4 > 0) { System.arraycopy(out, 4, newOut, 0, out.length - 4); } out = newOut; } } // 处理完整的4字节块 int fullBlocks = inlen / 4; if (fullBlocks > 0) { int[] keystream = new int[fullBlocks]; zuc256GenerateKeystream(ctx.state, fullBlocks, keystream); // 逐块异或加密 for (int i = 0; i < fullBlocks; i++) { int plain = getU32(in, i * 4); putU32(out, i * 4, plain ^ keystream[i]); } // 调整输入指针和长度 int processed = fullBlocks * 4; byte[] newIn = new byte[inlen - processed]; if (inlen - processed > 0) { System.arraycopy(in, processed, newIn, 0, inlen - processed); } in = newIn; inlen -= processed; } // 缓存剩余不足4字节的数据 if (inlen > 0) { System.arraycopy(in, 0, ctx.buf, 0, inlen); ctx.buflen = inlen; } } // 完成加密处理 public static void zuc256EncryptFinish(ZUC256EncryptCtx ctx, byte[] out) { if (ctx == null || out == null) return; // 处理缓冲区中剩余的不足4字节数据 if (ctx.buflen > 0) { int keystream = zuc256GenerateKeyword(ctx.state); byte[] keystreamBytes = new byte[4]; putU32(keystreamBytes, 0, keystream); // 逐字节异或 for (int i = 0; i < ctx.buflen; i++) { out[i] = (byte) (ctx.buf[i] ^ keystreamBytes[i]); } } // 清理上下文 Arrays.fill(ctx.buf, (byte) 0); ctx.buflen = 0; Arrays.fill(ctx.state.LFSR, 0); ctx.state.R1 = 0; ctx.state.R2 = 0; } // 一次性加密函数 public static void zuc256Crypt(ZUCState state, byte[] in, int inlen, byte[] out) { if (state == null || in == null || out == null) return; ZUC256EncryptCtx ctx = new ZUC256EncryptCtx(); // 复制状态 System.arraycopy(state.LFSR, 0, ctx.state.LFSR, 0, state.LFSR.length); ctx.state.R1 = state.R1; ctx.state.R2 = state.R2; // 执行加解密 zuc256EncryptUpdate(ctx, in, inlen, out); int remainingOffset = (inlen / 4) * 4; byte[] finishOut = new byte[out.length - remainingOffset]; if (finishOut.length > 0) { System.arraycopy(out, remainingOffset, finishOut, 0, finishOut.length); } zuc256EncryptFinish(ctx, finishOut); System.arraycopy(finishOut, 0, out, remainingOffset, finishOut.length); // 更新状态 System.arraycopy(ctx.state.LFSR, 0, state.LFSR, 0, ctx.state.LFSR.length); state.R1 = ctx.state.R1; state.R2 = ctx.state.R2; } // 提取IV public static void extractIv(byte[] input25Byte, byte[] output23Byte) { if (input25Byte == null || output23Byte == null) return; // 复制前17字节 System.arraycopy(input25Byte, 0, output23Byte, 0, 17); // 处理剩余8字节 byte[] src = new byte[8]; for (int i = 0; i < 8; i++) { src[i] = (byte) (input25Byte[17 + i] & 0x3F); } output23Byte[17] = (byte) ((src[0] << 2) | (src[1] >>> 4)); output23Byte[18] = (byte) (((src[1] & 0x0F) << 4) | (src[2] >>> 2)); output23Byte[19] = (byte) (((src[2] & 0x03) << 6) | src[3]); output23Byte[20] = (byte) ((src[4] << 2) | (src[5] >>> 4)); output23Byte[21] = (byte) (((src[5] & 0x0F) << 4) | (src[6] >>> 2)); output23Byte[22] = (byte) (((src[6] & 0x03) << 6) | src[7]); } // 打印字节数组为十六进制 public static void printHex(String label, byte[] data, int len) { System.out.print(label + ": "); for (int i = 0; i < len; i++) { System.out.printf("%02x ", data[i] & 0xFF); } System.out.println(); } // 主函数,验证ZUC256加解密功能 public static void main(String[] args) { // 1. 明文 byte[] plaintext = "ZUC256对称加解密测试:1234567890".getBytes(); int plaintextLen = plaintext.length; System.out.println("明文: " + new String(plaintext)); printHex("明文(十六进制)", plaintext, plaintextLen); // 2. 密钥(32字节ASCII) byte[] key = "0123456789abcdef0123456789abcdef".getBytes(); printHex("密钥", key, 32); // 3. 初始向量(25字节ASCII) byte[] inputIv25Byte = "0123456789abcdefg01234567".getBytes(); byte[] iv = new byte[23]; extractIv(inputIv25Byte, iv); printHex("提取后的IV", iv, 23); // 4. 分配加密/解密缓冲区 byte[] ciphertext = new byte[plaintextLen]; byte[] decryptedtext = new byte[plaintextLen]; // 5. 加密 ZUCState state = new ZUCState(); zuc256Init(state, key, iv); zuc256Crypt(state, plaintext, plaintextLen, ciphertext); printHex("密文", ciphertext, plaintextLen); // 6. 解密(重新初始化状态) zuc256Init(state, key, iv); zuc256Crypt(state, ciphertext, plaintextLen, decryptedtext); printHex("解密后", decryptedtext, plaintextLen); System.out.println("解密文本: " + new String(decryptedtext)); // 7. 验证结果 if (Arrays.equals(plaintext, decryptedtext)) { System.out.println("=== 测试成功: 解密结果与明文一致 ==="); } else { System.out.println("=== 测试失败: 解密结果与明文不一致 ==="); } } }