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626 lines
15 KiB
Common Lisp
626 lines
15 KiB
Common Lisp
/**
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* Author......: See docs/credits.txt
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* License.....: MIT
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*/
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#ifdef KERNEL_STATIC
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#include M2S(INCLUDE_PATH/inc_vendor.h)
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#include M2S(INCLUDE_PATH/inc_types.h)
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#include M2S(INCLUDE_PATH/inc_platform.cl)
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#include M2S(INCLUDE_PATH/inc_common.cl)
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#include M2S(INCLUDE_PATH/inc_hash_sha256.cl)
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#include M2S(INCLUDE_PATH/inc_cipher_aes.cl)
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#include M2S(INCLUDE_PATH/inc_cipher_twofish.cl)
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#endif
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#define COMPARE_S M2S(INCLUDE_PATH/inc_comp_single.cl)
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#define COMPARE_M M2S(INCLUDE_PATH/inc_comp_multi.cl)
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typedef struct keepass_tmp
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{
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u32 tmp_digest[8];
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} keepass_tmp_t;
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typedef struct keepass
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{
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u32 version;
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u32 algorithm;
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/* key-file handling */
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u32 keyfile_len;
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u32 keyfile[8];
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u32 final_random_seed[8];
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u32 transf_random_seed[8];
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u32 enc_iv[4];
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u32 contents_hash[8];
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/* specific to version 1 */
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u32 contents_len;
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u32 contents[0x200000];
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/* specific to version 2 */
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u32 expected_bytes[8];
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} keepass_t;
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KERNEL_FQ void m29700_init (KERN_ATTR_TMPS_ESALT (keepass_tmp_t, keepass_t))
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{
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/**
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* base
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*/
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const u64 gid = get_global_id (0);
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if (gid >= GID_CNT) return;
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sha256_ctx_t ctx;
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sha256_init (&ctx);
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sha256_update_global_swap (&ctx, pws[gid].i, pws[gid].pw_len);
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sha256_final (&ctx);
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u32 digest[8];
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digest[0] = ctx.h[0];
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digest[1] = ctx.h[1];
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digest[2] = ctx.h[2];
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digest[3] = ctx.h[3];
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digest[4] = ctx.h[4];
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digest[5] = ctx.h[5];
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digest[6] = ctx.h[6];
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digest[7] = ctx.h[7];
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tmps[gid].tmp_digest[0] = digest[0];
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tmps[gid].tmp_digest[1] = digest[1];
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tmps[gid].tmp_digest[2] = digest[2];
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tmps[gid].tmp_digest[3] = digest[3];
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tmps[gid].tmp_digest[4] = digest[4];
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tmps[gid].tmp_digest[5] = digest[5];
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tmps[gid].tmp_digest[6] = digest[6];
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tmps[gid].tmp_digest[7] = digest[7];
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}
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KERNEL_FQ void m29700_loop (KERN_ATTR_TMPS_ESALT (keepass_tmp_t, keepass_t))
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{
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const u64 gid = get_global_id (0);
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const u64 lid = get_local_id (0);
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const u64 lsz = get_local_size (0);
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/**
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* aes shared
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*/
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#ifdef REAL_SHM
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LOCAL_VK u32 s_te0[256];
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LOCAL_VK u32 s_te1[256];
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LOCAL_VK u32 s_te2[256];
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LOCAL_VK u32 s_te3[256];
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LOCAL_VK u32 s_te4[256];
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for (u32 i = lid; i < 256; i += lsz)
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{
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s_te0[i] = te0[i];
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s_te1[i] = te1[i];
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s_te2[i] = te2[i];
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s_te3[i] = te3[i];
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s_te4[i] = te4[i];
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}
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SYNC_THREADS ();
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#else
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CONSTANT_AS u32a *s_te0 = te0;
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CONSTANT_AS u32a *s_te1 = te1;
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CONSTANT_AS u32a *s_te2 = te2;
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CONSTANT_AS u32a *s_te3 = te3;
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CONSTANT_AS u32a *s_te4 = te4;
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#endif
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if (gid >= GID_CNT) return;
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/* Construct AES key */
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u32 ukey[8];
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ukey[0] = esalt_bufs[DIGESTS_OFFSET_HOST].transf_random_seed[0];
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ukey[1] = esalt_bufs[DIGESTS_OFFSET_HOST].transf_random_seed[1];
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ukey[2] = esalt_bufs[DIGESTS_OFFSET_HOST].transf_random_seed[2];
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ukey[3] = esalt_bufs[DIGESTS_OFFSET_HOST].transf_random_seed[3];
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ukey[4] = esalt_bufs[DIGESTS_OFFSET_HOST].transf_random_seed[4];
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ukey[5] = esalt_bufs[DIGESTS_OFFSET_HOST].transf_random_seed[5];
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ukey[6] = esalt_bufs[DIGESTS_OFFSET_HOST].transf_random_seed[6];
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ukey[7] = esalt_bufs[DIGESTS_OFFSET_HOST].transf_random_seed[7];
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#define KEYLEN 60
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u32 ks[KEYLEN];
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AES256_set_encrypt_key (ks, ukey, s_te0, s_te1, s_te2, s_te3);
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u32 data0[4];
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u32 data1[4];
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data0[0] = tmps[gid].tmp_digest[0];
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data0[1] = tmps[gid].tmp_digest[1];
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data0[2] = tmps[gid].tmp_digest[2];
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data0[3] = tmps[gid].tmp_digest[3];
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data1[0] = tmps[gid].tmp_digest[4];
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data1[1] = tmps[gid].tmp_digest[5];
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data1[2] = tmps[gid].tmp_digest[6];
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data1[3] = tmps[gid].tmp_digest[7];
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for (u32 i = 0; i < LOOP_CNT; i++)
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{
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AES256_encrypt (ks, data0, data0, s_te0, s_te1, s_te2, s_te3, s_te4);
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AES256_encrypt (ks, data1, data1, s_te0, s_te1, s_te2, s_te3, s_te4);
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}
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tmps[gid].tmp_digest[0] = data0[0];
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tmps[gid].tmp_digest[1] = data0[1];
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tmps[gid].tmp_digest[2] = data0[2];
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tmps[gid].tmp_digest[3] = data0[3];
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tmps[gid].tmp_digest[4] = data1[0];
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tmps[gid].tmp_digest[5] = data1[1];
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tmps[gid].tmp_digest[6] = data1[2];
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tmps[gid].tmp_digest[7] = data1[3];
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}
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KERNEL_FQ void m29700_comp (KERN_ATTR_TMPS_ESALT (keepass_tmp_t, keepass_t))
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{
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const u64 gid = get_global_id (0);
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const u64 lid = get_local_id (0);
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const u64 lsz = get_local_size (0);
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/**
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* aes shared
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*/
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#ifdef REAL_SHM
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LOCAL_VK u32 s_td0[256];
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LOCAL_VK u32 s_td1[256];
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LOCAL_VK u32 s_td2[256];
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LOCAL_VK u32 s_td3[256];
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LOCAL_VK u32 s_td4[256];
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LOCAL_VK u32 s_te0[256];
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LOCAL_VK u32 s_te1[256];
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LOCAL_VK u32 s_te2[256];
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LOCAL_VK u32 s_te3[256];
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LOCAL_VK u32 s_te4[256];
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for (u32 i = lid; i < 256; i += lsz)
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{
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s_td0[i] = td0[i];
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s_td1[i] = td1[i];
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s_td2[i] = td2[i];
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s_td3[i] = td3[i];
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s_td4[i] = td4[i];
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s_te0[i] = te0[i];
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s_te1[i] = te1[i];
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s_te2[i] = te2[i];
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s_te3[i] = te3[i];
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s_te4[i] = te4[i];
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}
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SYNC_THREADS ();
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#else
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CONSTANT_AS u32a *s_td0 = td0;
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CONSTANT_AS u32a *s_td1 = td1;
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CONSTANT_AS u32a *s_td2 = td2;
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CONSTANT_AS u32a *s_td3 = td3;
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CONSTANT_AS u32a *s_td4 = td4;
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CONSTANT_AS u32a *s_te0 = te0;
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CONSTANT_AS u32a *s_te1 = te1;
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CONSTANT_AS u32a *s_te2 = te2;
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CONSTANT_AS u32a *s_te3 = te3;
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CONSTANT_AS u32a *s_te4 = te4;
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#endif
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if (gid >= GID_CNT) return;
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/* hash output... */
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u32 w0[4];
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u32 w1[4];
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u32 w2[4];
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u32 w3[4];
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w0[0] = tmps[gid].tmp_digest[0];
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w0[1] = tmps[gid].tmp_digest[1];
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w0[2] = tmps[gid].tmp_digest[2];
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w0[3] = tmps[gid].tmp_digest[3];
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w1[0] = tmps[gid].tmp_digest[4];
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w1[1] = tmps[gid].tmp_digest[5];
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w1[2] = tmps[gid].tmp_digest[6];
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w1[3] = tmps[gid].tmp_digest[7];
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w2[0] = 0;
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w2[1] = 0;
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w2[2] = 0;
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w2[3] = 0;
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w3[0] = 0;
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w3[1] = 0;
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w3[2] = 0;
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w3[3] = 0;
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sha256_ctx_t ctx;
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sha256_init (&ctx);
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sha256_update_64 (&ctx, w0, w1, w2, w3, 32);
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sha256_final (&ctx);
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u32 digest[8];
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digest[0] = ctx.h[0];
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digest[1] = ctx.h[1];
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digest[2] = ctx.h[2];
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digest[3] = ctx.h[3];
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digest[4] = ctx.h[4];
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digest[5] = ctx.h[5];
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digest[6] = ctx.h[6];
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digest[7] = ctx.h[7];
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/* ...then hash final_random_seed | output */
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if (esalt_bufs[DIGESTS_OFFSET_HOST].version == 1)
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{
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w0[0] = esalt_bufs[DIGESTS_OFFSET_HOST].final_random_seed[0];
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w0[1] = esalt_bufs[DIGESTS_OFFSET_HOST].final_random_seed[1];
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w0[2] = esalt_bufs[DIGESTS_OFFSET_HOST].final_random_seed[2];
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w0[3] = esalt_bufs[DIGESTS_OFFSET_HOST].final_random_seed[3];
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w1[0] = digest[0];
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w1[1] = digest[1];
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w1[2] = digest[2];
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w1[3] = digest[3];
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w2[0] = digest[4];
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w2[1] = digest[5];
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w2[2] = digest[6];
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w2[3] = digest[7];
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w3[0] = 0;
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w3[1] = 0;
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w3[2] = 0;
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w3[3] = 0;
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sha256_init (&ctx);
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sha256_update_64 (&ctx, w0, w1, w2, w3, 48);
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sha256_final (&ctx);
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digest[0] = ctx.h[0];
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digest[1] = ctx.h[1];
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digest[2] = ctx.h[2];
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digest[3] = ctx.h[3];
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digest[4] = ctx.h[4];
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digest[5] = ctx.h[5];
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digest[6] = ctx.h[6];
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digest[7] = ctx.h[7];
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}
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else
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{
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w0[0] = esalt_bufs[DIGESTS_OFFSET_HOST].final_random_seed[0];
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w0[1] = esalt_bufs[DIGESTS_OFFSET_HOST].final_random_seed[1];
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w0[2] = esalt_bufs[DIGESTS_OFFSET_HOST].final_random_seed[2];
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w0[3] = esalt_bufs[DIGESTS_OFFSET_HOST].final_random_seed[3];
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w1[0] = esalt_bufs[DIGESTS_OFFSET_HOST].final_random_seed[4];
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w1[1] = esalt_bufs[DIGESTS_OFFSET_HOST].final_random_seed[5];
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w1[2] = esalt_bufs[DIGESTS_OFFSET_HOST].final_random_seed[6];
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w1[3] = esalt_bufs[DIGESTS_OFFSET_HOST].final_random_seed[7];
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w2[0] = digest[0];
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w2[1] = digest[1];
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w2[2] = digest[2];
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w2[3] = digest[3];
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w3[0] = digest[4];
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w3[1] = digest[5];
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w3[2] = digest[6];
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w3[3] = digest[7];
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sha256_init (&ctx);
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sha256_update_64 (&ctx, w0, w1, w2, w3, 64);
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sha256_final (&ctx);
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digest[0] = ctx.h[0];
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digest[1] = ctx.h[1];
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digest[2] = ctx.h[2];
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digest[3] = ctx.h[3];
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digest[4] = ctx.h[4];
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digest[5] = ctx.h[5];
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digest[6] = ctx.h[6];
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digest[7] = ctx.h[7];
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}
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// at this point we have to distinguish between the different keypass versions
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u32 iv[4];
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iv[0] = esalt_bufs[DIGESTS_OFFSET_HOST].enc_iv[0];
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iv[1] = esalt_bufs[DIGESTS_OFFSET_HOST].enc_iv[1];
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iv[2] = esalt_bufs[DIGESTS_OFFSET_HOST].enc_iv[2];
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iv[3] = esalt_bufs[DIGESTS_OFFSET_HOST].enc_iv[3];
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u32 r0 = 0;
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u32 r1 = 0;
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u32 r2 = 0;
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u32 r3 = 0;
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if (esalt_bufs[DIGESTS_OFFSET_HOST].version == 1)
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{
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sha256_ctx_t ctx;
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sha256_init (&ctx);
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if (esalt_bufs[DIGESTS_OFFSET_HOST].algorithm == 1)
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{
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/* Construct final Twofish key */
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u32 sk[4];
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u32 lk[40];
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digest[0] = hc_swap32_S (digest[0]);
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digest[1] = hc_swap32_S (digest[1]);
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digest[2] = hc_swap32_S (digest[2]);
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digest[3] = hc_swap32_S (digest[3]);
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digest[4] = hc_swap32_S (digest[4]);
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digest[5] = hc_swap32_S (digest[5]);
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digest[6] = hc_swap32_S (digest[6]);
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digest[7] = hc_swap32_S (digest[7]);
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twofish256_set_key (sk, lk, digest);
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iv[0] = hc_swap32_S (iv[0]);
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iv[1] = hc_swap32_S (iv[1]);
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iv[2] = hc_swap32_S (iv[2]);
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iv[3] = hc_swap32_S (iv[3]);
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u32 contents_len = esalt_bufs[DIGESTS_OFFSET_HOST].contents_len;
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u32 contents_pos;
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u32 contents_off;
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// process (decrypt and hash) the buffer with the biggest steps possible.
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for (contents_pos = 0, contents_off = 0; contents_pos < contents_len - 16; contents_pos += 16, contents_off += 4)
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{
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u32 data[4];
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data[0] = esalt_bufs[DIGESTS_OFFSET_HOST].contents[contents_off + 0];
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data[1] = esalt_bufs[DIGESTS_OFFSET_HOST].contents[contents_off + 1];
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data[2] = esalt_bufs[DIGESTS_OFFSET_HOST].contents[contents_off + 2];
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data[3] = esalt_bufs[DIGESTS_OFFSET_HOST].contents[contents_off + 3];
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data[0] = hc_swap32_S (data[0]);
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data[1] = hc_swap32_S (data[1]);
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data[2] = hc_swap32_S (data[2]);
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data[3] = hc_swap32_S (data[3]);
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u32 out[4];
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twofish256_decrypt (sk, lk, data, out);
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out[0] ^= iv[0];
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out[1] ^= iv[1];
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out[2] ^= iv[2];
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out[3] ^= iv[3];
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out[0] = hc_swap32_S (out[0]);
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out[1] = hc_swap32_S (out[1]);
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out[2] = hc_swap32_S (out[2]);
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out[3] = hc_swap32_S (out[3]);
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u32 w0[4] = { 0 };
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u32 w1[4] = { 0 };
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u32 w2[4] = { 0 };
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u32 w3[4] = { 0 };
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w0[0] = out[0];
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w0[1] = out[1];
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w0[2] = out[2];
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w0[3] = out[3];
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sha256_update_64 (&ctx, w0, w1, w2, w3, 16);
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iv[0] = data[0];
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iv[1] = data[1];
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iv[2] = data[2];
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iv[3] = data[3];
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}
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// we've reached the final block for decrypt, it will contain the padding bytes we're looking for
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u32 data[4];
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data[0] = esalt_bufs[DIGESTS_OFFSET_HOST].contents[contents_off + 0];
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data[1] = esalt_bufs[DIGESTS_OFFSET_HOST].contents[contents_off + 1];
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data[2] = esalt_bufs[DIGESTS_OFFSET_HOST].contents[contents_off + 2];
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data[3] = esalt_bufs[DIGESTS_OFFSET_HOST].contents[contents_off + 3];
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data[0] = hc_swap32_S (data[0]);
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data[1] = hc_swap32_S (data[1]);
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data[2] = hc_swap32_S (data[2]);
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data[3] = hc_swap32_S (data[3]);
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u32 out[4];
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twofish256_decrypt (sk, lk, data, out);
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out[0] ^= iv[0];
|
|
out[1] ^= iv[1];
|
|
out[2] ^= iv[2];
|
|
out[3] ^= iv[3];
|
|
|
|
out[0] = hc_swap32_S (out[0]);
|
|
out[1] = hc_swap32_S (out[1]);
|
|
out[2] = hc_swap32_S (out[2]);
|
|
out[3] = hc_swap32_S (out[3]);
|
|
|
|
// now we can access the pad byte
|
|
|
|
const u32 pad_byte = out[3] & 0xff;
|
|
|
|
// we need to clear the buffer of the padding data
|
|
|
|
truncate_block_4x4_be_S (out, 16 - pad_byte);
|
|
|
|
u32 w0[4] = { 0 };
|
|
u32 w1[4] = { 0 };
|
|
u32 w2[4] = { 0 };
|
|
u32 w3[4] = { 0 };
|
|
|
|
w0[0] = out[0];
|
|
w0[1] = out[1];
|
|
w0[2] = out[2];
|
|
w0[3] = out[3];
|
|
|
|
sha256_update_64 (&ctx, w0, w1, w2, w3, 16 - pad_byte);
|
|
}
|
|
else
|
|
{
|
|
/* Construct final AES key */
|
|
|
|
#define KEYLEN 60
|
|
|
|
u32 ks[KEYLEN];
|
|
|
|
AES256_set_decrypt_key (ks, digest, s_te0, s_te1, s_te2, s_te3, s_td0, s_td1, s_td2, s_td3);
|
|
|
|
u32 contents_len = esalt_bufs[DIGESTS_OFFSET_HOST].contents_len;
|
|
|
|
u32 contents_pos;
|
|
u32 contents_off;
|
|
|
|
for (contents_pos = 0, contents_off = 0; contents_pos < contents_len - 16; contents_pos += 16, contents_off += 4)
|
|
{
|
|
u32 data[4];
|
|
|
|
data[0] = esalt_bufs[DIGESTS_OFFSET_HOST].contents[contents_off + 0];
|
|
data[1] = esalt_bufs[DIGESTS_OFFSET_HOST].contents[contents_off + 1];
|
|
data[2] = esalt_bufs[DIGESTS_OFFSET_HOST].contents[contents_off + 2];
|
|
data[3] = esalt_bufs[DIGESTS_OFFSET_HOST].contents[contents_off + 3];
|
|
|
|
u32 out[4];
|
|
|
|
AES256_decrypt (ks, data, out, s_td0, s_td1, s_td2, s_td3, s_td4);
|
|
|
|
out[0] ^= iv[0];
|
|
out[1] ^= iv[1];
|
|
out[2] ^= iv[2];
|
|
out[3] ^= iv[3];
|
|
|
|
u32 w0[4] = { 0 };
|
|
u32 w1[4] = { 0 };
|
|
u32 w2[4] = { 0 };
|
|
u32 w3[4] = { 0 };
|
|
|
|
w0[0] = out[0];
|
|
w0[1] = out[1];
|
|
w0[2] = out[2];
|
|
w0[3] = out[3];
|
|
|
|
sha256_update_64 (&ctx, w0, w1, w2, w3, 16);
|
|
|
|
iv[0] = data[0];
|
|
iv[1] = data[1];
|
|
iv[2] = data[2];
|
|
iv[3] = data[3];
|
|
}
|
|
|
|
// we've reached the final block for decrypt, it will contain the padding bytes we're looking for
|
|
|
|
u32 data[4];
|
|
|
|
data[0] = esalt_bufs[DIGESTS_OFFSET_HOST].contents[contents_off + 0];
|
|
data[1] = esalt_bufs[DIGESTS_OFFSET_HOST].contents[contents_off + 1];
|
|
data[2] = esalt_bufs[DIGESTS_OFFSET_HOST].contents[contents_off + 2];
|
|
data[3] = esalt_bufs[DIGESTS_OFFSET_HOST].contents[contents_off + 3];
|
|
|
|
u32 out[4];
|
|
|
|
AES256_decrypt (ks, data, out, s_td0, s_td1, s_td2, s_td3, s_td4);
|
|
|
|
out[0] ^= iv[0];
|
|
out[1] ^= iv[1];
|
|
out[2] ^= iv[2];
|
|
out[3] ^= iv[3];
|
|
|
|
// now we can access the pad byte
|
|
|
|
const u32 pad_byte = out[3] & 0xff;
|
|
|
|
// we need to clear the buffer of the padding data
|
|
|
|
truncate_block_4x4_be_S (out, 16 - pad_byte);
|
|
|
|
u32 w0[4] = { 0 };
|
|
u32 w1[4] = { 0 };
|
|
u32 w2[4] = { 0 };
|
|
u32 w3[4] = { 0 };
|
|
|
|
w0[0] = out[0];
|
|
w0[1] = out[1];
|
|
w0[2] = out[2];
|
|
w0[3] = out[3];
|
|
|
|
sha256_update_64 (&ctx, w0, w1, w2, w3, 16 - pad_byte);
|
|
}
|
|
|
|
sha256_final (&ctx);
|
|
|
|
r0 = ctx.h[0];
|
|
r1 = ctx.h[1];
|
|
r2 = ctx.h[2];
|
|
r3 = ctx.h[3];
|
|
}
|
|
else
|
|
{
|
|
/* Construct final AES key */
|
|
|
|
#define KEYLEN 60
|
|
|
|
u32 ks[KEYLEN];
|
|
|
|
AES256_set_decrypt_key (ks, digest, s_te0, s_te1, s_te2, s_te3, s_td0, s_td1, s_td2, s_td3);
|
|
|
|
u32 data[4];
|
|
|
|
data[0] = esalt_bufs[DIGESTS_OFFSET_HOST].contents_hash[0];
|
|
data[1] = esalt_bufs[DIGESTS_OFFSET_HOST].contents_hash[1];
|
|
data[2] = esalt_bufs[DIGESTS_OFFSET_HOST].contents_hash[2];
|
|
data[3] = esalt_bufs[DIGESTS_OFFSET_HOST].contents_hash[3];
|
|
|
|
u32 out[4];
|
|
|
|
AES256_decrypt (ks, data, out, s_td0, s_td1, s_td2, s_td3, s_td4);
|
|
|
|
out[0] ^= iv[0];
|
|
out[1] ^= iv[1];
|
|
out[2] ^= iv[2];
|
|
out[3] ^= iv[3];
|
|
|
|
r0 = out[0];
|
|
r1 = out[1];
|
|
r2 = out[2];
|
|
r3 = out[3];
|
|
}
|
|
|
|
#define il_pos 0
|
|
|
|
#ifdef KERNEL_STATIC
|
|
#include COMPARE_M
|
|
#endif
|
|
}
|