/* * Copyright (C) 2013 Andrea Mazzoleni * * This program is free software: you can redistribute it and/or modify * it under the terms of the GNU General Public License as published by * the Free Software Foundation, either version 2 of the License, or * (at your option) any later version. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. */ #include "internal.h" #include "gf.h" /* * GEN1 (RAID5 with xor) 32bit C implementation */ void raid_gen1_int32(int nd, size_t size, void **vv) { uint8_t **v = (uint8_t **)vv; uint8_t *p; int d, l; size_t i; uint32_t p0; uint32_t p1; l = nd - 1; p = v[nd]; for (i = 0; i < size; i += 8) { p0 = v_32(v[l][i]); p1 = v_32(v[l][i + 4]); for (d = l - 1; d >= 0; --d) { p0 ^= v_32(v[d][i]); p1 ^= v_32(v[d][i + 4]); } v_32(p[i]) = p0; v_32(p[i + 4]) = p1; } } /* * GEN1 (RAID5 with xor) 64bit C implementation */ void raid_gen1_int64(int nd, size_t size, void **vv) { uint8_t **v = (uint8_t **)vv; uint8_t *p; int d, l; size_t i; uint64_t p0; uint64_t p1; l = nd - 1; p = v[nd]; for (i = 0; i < size; i += 16) { p0 = v_64(v[l][i]); p1 = v_64(v[l][i + 8]); for (d = l - 1; d >= 0; --d) { p0 ^= v_64(v[d][i]); p1 ^= v_64(v[d][i + 8]); } v_64(p[i]) = p0; v_64(p[i + 8]) = p1; } } /* * GEN2 (RAID6 with powers of 2) 32bit C implementation */ void raid_gen2_int32(int nd, size_t size, void **vv) { uint8_t **v = (uint8_t **)vv; uint8_t *p; uint8_t *q; int d, l; size_t i; uint32_t d0, q0, p0; uint32_t d1, q1, p1; l = nd - 1; p = v[nd]; q = v[nd + 1]; for (i = 0; i < size; i += 8) { q0 = p0 = v_32(v[l][i]); q1 = p1 = v_32(v[l][i + 4]); for (d = l - 1; d >= 0; --d) { d0 = v_32(v[d][i]); d1 = v_32(v[d][i + 4]); p0 ^= d0; p1 ^= d1; q0 = x2_32(q0); q1 = x2_32(q1); q0 ^= d0; q1 ^= d1; } v_32(p[i]) = p0; v_32(p[i + 4]) = p1; v_32(q[i]) = q0; v_32(q[i + 4]) = q1; } } /* * GEN2 (RAID6 with powers of 2) 64bit C implementation */ void raid_gen2_int64(int nd, size_t size, void **vv) { uint8_t **v = (uint8_t **)vv; uint8_t *p; uint8_t *q; int d, l; size_t i; uint64_t d0, q0, p0; uint64_t d1, q1, p1; l = nd - 1; p = v[nd]; q = v[nd + 1]; for (i = 0; i < size; i += 16) { q0 = p0 = v_64(v[l][i]); q1 = p1 = v_64(v[l][i + 8]); for (d = l - 1; d >= 0; --d) { d0 = v_64(v[d][i]); d1 = v_64(v[d][i + 8]); p0 ^= d0; p1 ^= d1; q0 = x2_64(q0); q1 = x2_64(q1); q0 ^= d0; q1 ^= d1; } v_64(p[i]) = p0; v_64(p[i + 8]) = p1; v_64(q[i]) = q0; v_64(q[i + 8]) = q1; } } /* * GEN3 (triple parity with Cauchy matrix) 8bit C implementation * * Note that instead of a generic multiplication table, likely resulting * in multiple cache misses, a precomputed table could be used. * But this is only a kind of reference function, and we are not really * interested in speed. */ void raid_gen3_int8(int nd, size_t size, void **vv) { uint8_t **v = (uint8_t **)vv; uint8_t *p; uint8_t *q; uint8_t *r; int d, l; size_t i; uint8_t d0, r0, q0, p0; l = nd - 1; p = v[nd]; q = v[nd + 1]; r = v[nd + 2]; for (i = 0; i < size; i += 1) { p0 = q0 = r0 = 0; for (d = l; d > 0; --d) { d0 = v_8(v[d][i]); p0 ^= d0; q0 ^= gfmul[d0][gfgen[1][d]]; r0 ^= gfmul[d0][gfgen[2][d]]; } /* first disk with all coefficients at 1 */ d0 = v_8(v[0][i]); p0 ^= d0; q0 ^= d0; r0 ^= d0; v_8(p[i]) = p0; v_8(q[i]) = q0; v_8(r[i]) = r0; } } /* * GEN4 (quad parity with Cauchy matrix) 8bit C implementation * * Note that instead of a generic multiplication table, likely resulting * in multiple cache misses, a precomputed table could be used. * But this is only a kind of reference function, and we are not really * interested in speed. */ void raid_gen4_int8(int nd, size_t size, void **vv) { uint8_t **v = (uint8_t **)vv; uint8_t *p; uint8_t *q; uint8_t *r; uint8_t *s; int d, l; size_t i; uint8_t d0, s0, r0, q0, p0; l = nd - 1; p = v[nd]; q = v[nd + 1]; r = v[nd + 2]; s = v[nd + 3]; for (i = 0; i < size; i += 1) { p0 = q0 = r0 = s0 = 0; for (d = l; d > 0; --d) { d0 = v_8(v[d][i]); p0 ^= d0; q0 ^= gfmul[d0][gfgen[1][d]]; r0 ^= gfmul[d0][gfgen[2][d]]; s0 ^= gfmul[d0][gfgen[3][d]]; } /* first disk with all coefficients at 1 */ d0 = v_8(v[0][i]); p0 ^= d0; q0 ^= d0; r0 ^= d0; s0 ^= d0; v_8(p[i]) = p0; v_8(q[i]) = q0; v_8(r[i]) = r0; v_8(s[i]) = s0; } } /* * GEN5 (penta parity with Cauchy matrix) 8bit C implementation * * Note that instead of a generic multiplication table, likely resulting * in multiple cache misses, a precomputed table could be used. * But this is only a kind of reference function, and we are not really * interested in speed. */ void raid_gen5_int8(int nd, size_t size, void **vv) { uint8_t **v = (uint8_t **)vv; uint8_t *p; uint8_t *q; uint8_t *r; uint8_t *s; uint8_t *t; int d, l; size_t i; uint8_t d0, t0, s0, r0, q0, p0; l = nd - 1; p = v[nd]; q = v[nd + 1]; r = v[nd + 2]; s = v[nd + 3]; t = v[nd + 4]; for (i = 0; i < size; i += 1) { p0 = q0 = r0 = s0 = t0 = 0; for (d = l; d > 0; --d) { d0 = v_8(v[d][i]); p0 ^= d0; q0 ^= gfmul[d0][gfgen[1][d]]; r0 ^= gfmul[d0][gfgen[2][d]]; s0 ^= gfmul[d0][gfgen[3][d]]; t0 ^= gfmul[d0][gfgen[4][d]]; } /* first disk with all coefficients at 1 */ d0 = v_8(v[0][i]); p0 ^= d0; q0 ^= d0; r0 ^= d0; s0 ^= d0; t0 ^= d0; v_8(p[i]) = p0; v_8(q[i]) = q0; v_8(r[i]) = r0; v_8(s[i]) = s0; v_8(t[i]) = t0; } } /* * GEN6 (hexa parity with Cauchy matrix) 8bit C implementation * * Note that instead of a generic multiplication table, likely resulting * in multiple cache misses, a precomputed table could be used. * But this is only a kind of reference function, and we are not really * interested in speed. */ void raid_gen6_int8(int nd, size_t size, void **vv) { uint8_t **v = (uint8_t **)vv; uint8_t *p; uint8_t *q; uint8_t *r; uint8_t *s; uint8_t *t; uint8_t *u; int d, l; size_t i; uint8_t d0, u0, t0, s0, r0, q0, p0; l = nd - 1; p = v[nd]; q = v[nd + 1]; r = v[nd + 2]; s = v[nd + 3]; t = v[nd + 4]; u = v[nd + 5]; for (i = 0; i < size; i += 1) { p0 = q0 = r0 = s0 = t0 = u0 = 0; for (d = l; d > 0; --d) { d0 = v_8(v[d][i]); p0 ^= d0; q0 ^= gfmul[d0][gfgen[1][d]]; r0 ^= gfmul[d0][gfgen[2][d]]; s0 ^= gfmul[d0][gfgen[3][d]]; t0 ^= gfmul[d0][gfgen[4][d]]; u0 ^= gfmul[d0][gfgen[5][d]]; } /* first disk with all coefficients at 1 */ d0 = v_8(v[0][i]); p0 ^= d0; q0 ^= d0; r0 ^= d0; s0 ^= d0; t0 ^= d0; u0 ^= d0; v_8(p[i]) = p0; v_8(q[i]) = q0; v_8(r[i]) = r0; v_8(s[i]) = s0; v_8(t[i]) = t0; v_8(u[i]) = u0; } } /* * Recover failure of one data block at index id[0] using parity at index * ip[0] for any RAID level. * * Starting from the equation: * * Pd = A[ip[0],id[0]] * Dx * * and solving we get: * * Dx = A[ip[0],id[0]]^-1 * Pd */ void raid_rec1_int8(int nr, int *id, int *ip, int nd, size_t size, void **vv) { uint8_t **v = (uint8_t **)vv; uint8_t *p; uint8_t *pa; const uint8_t *T; uint8_t G; uint8_t V; size_t i; (void)nr; /* unused, it's always 1 */ /* if it's RAID5 uses the faster function */ if (ip[0] == 0) { raid_rec1of1(id, nd, size, vv); return; } /* setup the coefficients matrix */ G = A(ip[0], id[0]); /* invert it to solve the system of linear equations */ V = inv(G); /* get multiplication tables */ T = table(V); /* compute delta parity */ raid_delta_gen(1, id, ip, nd, size, vv); p = v[nd + ip[0]]; pa = v[id[0]]; for (i = 0; i < size; ++i) { /* delta */ uint8_t Pd = p[i] ^ pa[i]; /* reconstruct */ pa[i] = T[Pd]; } } /* * Recover failure of two data blocks at indexes id[0],id[1] using parity at * indexes ip[0],ip[1] for any RAID level. * * Starting from the equations: * * Pd = A[ip[0],id[0]] * Dx + A[ip[0],id[1]] * Dy * Qd = A[ip[1],id[0]] * Dx + A[ip[1],id[1]] * Dy * * we solve inverting the coefficients matrix. */ void raid_rec2_int8(int nr, int *id, int *ip, int nd, size_t size, void **vv) { uint8_t **v = (uint8_t **)vv; uint8_t *p; uint8_t *pa; uint8_t *q; uint8_t *qa; const int N = 2; const uint8_t *T[N][N]; uint8_t G[N * N]; uint8_t V[N * N]; size_t i; int j, k; (void)nr; /* unused, it's always 2 */ /* if it's RAID6 recovering with P and Q uses the faster function */ if (ip[0] == 0 && ip[1] == 1) { raid_rec2of2_int8(id, ip, nd, size, vv); return; } /* setup the coefficients matrix */ for (j = 0; j < N; ++j) for (k = 0; k < N; ++k) G[j * N + k] = A(ip[j], id[k]); /* invert it to solve the system of linear equations */ raid_invert(G, V, N); /* get multiplication tables */ for (j = 0; j < N; ++j) for (k = 0; k < N; ++k) T[j][k] = table(V[j * N + k]); /* compute delta parity */ raid_delta_gen(2, id, ip, nd, size, vv); p = v[nd + ip[0]]; q = v[nd + ip[1]]; pa = v[id[0]]; qa = v[id[1]]; for (i = 0; i < size; ++i) { /* delta */ uint8_t Pd = p[i] ^ pa[i]; uint8_t Qd = q[i] ^ qa[i]; /* reconstruct */ pa[i] = T[0][0][Pd] ^ T[0][1][Qd]; qa[i] = T[1][0][Pd] ^ T[1][1][Qd]; } } /* * Recover failure of N data blocks at indexes id[N] using parity at indexes * ip[N] for any RAID level. * * Starting from the N equations, with 0<=i