decode_rs.c source code [linux/lib/reed_solomon/decode_rs.c]

1	// SPDX-License-Identifier: GPL-2.0
2	/*
3	* Generic Reed Solomon encoder / decoder library
4	*
5	* Copyright 2002, Phil Karn, KA9Q
6	* May be used under the terms of the GNU General Public License (GPL)
7	*
8	* Adaption to the kernel by Thomas Gleixner (tglx@linutronix.de)
9	*
10	* Generic data width independent code which is included by the wrappers.
11	*/
12	{
13	struct rs_codec *rs = rsc->codec;
14	int deg_lambda, el, deg_omega;
15	int i, j, r, k, pad;
16	int nn = rs->nn;
17	int nroots = rs->nroots;
18	int fcr = rs->fcr;
19	int prim = rs->prim;
20	int iprim = rs->iprim;
21	uint16_t *alpha_to = rs->alpha_to;
22	uint16_t *index_of = rs->index_of;
23	uint16_t u, q, tmp, num1, num2, den, discr_r, syn_error;
24	int count = `0`;
25	int num_corrected;
26	uint16_t msk = (uint16_t) rs->nn;
27
28	/*
29	* The decoder buffers are in the rs control struct. They are
30	* arrays sized [nroots + 1]
31	*/
32	uint16_t lambda = rsc->buffers + RS_DECODE_LAMBDA (nroots + `1`);
33	uint16_t syn = rsc->buffers + RS_DECODE_SYN (nroots + `1`);
34	uint16_t b = rsc->buffers + RS_DECODE_B (nroots + `1`);
35	uint16_t t = rsc->buffers + RS_DECODE_T (nroots + `1`);
36	uint16_t omega = rsc->buffers + RS_DECODE_OMEGA (nroots + `1`);
37	uint16_t root = rsc->buffers + RS_DECODE_ROOT (nroots + `1`);
38	uint16_t reg = rsc->buffers + RS_DECODE_REG (nroots + `1`);
39	uint16_t loc = rsc->buffers + RS_DECODE_LOC (nroots + `1`);
40
41	/ Check length parameter for validity /
42	pad = nn - nroots - len;
43	BUG_ON(pad < `0` \|\| pad >= nn - nroots);
44
45	/ Does the caller provide the syndrome ? /
46	if (s != NULL) {
47	for (i = `0`; i < nroots; i++) {
48	/ The syndrome is in index form,*
49	* so nn represents zero
50	*/
51	if (s[i] != nn)
52	goto decode;
53	}
54
55	/ syndrome is zero, no errors to correct /
56	return `0`;
57	}
58
59	/ form the syndromes; i.e., evaluate data(x) at roots of*
60	* g(x) */
61	for (i = `0`; i < nroots; i++)
62	syn[i] = (((uint16_t) data[`0`]) ^ invmsk) & msk;
63
64	for (j = `1`; j < len; j++) {
65	for (i = `0`; i < nroots; i++) {
66	if (syn[i] == `0`) {
67	syn[i] = (((uint16_t) data[j]) ^
68	invmsk) & msk;
69	} else {
70	syn[i] = ((((uint16_t) data[j]) ^
71	invmsk) & msk) ^
72	alpha_to[rs_modnn(rs, index_of[syn[i]] +
73	(fcr + i) * prim)];
74	}
75	}
76	}
77
78	for (j = `0`; j < nroots; j++) {
79	for (i = `0`; i < nroots; i++) {
80	if (syn[i] == `0`) {
81	syn[i] = ((uint16_t) par[j]) & msk;
82	} else {
83	syn[i] = (((uint16_t) par[j]) & msk) ^
84	alpha_to[rs_modnn(rs, index_of[syn[i]] +
85	(fcr+i)*prim)];
86	}
87	}
88	}
89	s = syn;
90
91	/ Convert syndromes to index form, checking for nonzero condition /
92	syn_error = `0`;
93	for (i = `0`; i < nroots; i++) {
94	syn_error \|= s[i];
95	s[i] = index_of[s[i]];
96	}
97
98	if (!syn_error) {
99	/ if syndrome is zero, data[] is a codeword and there are no*
100	* errors to correct. So return data[] unmodified
101	*/
102	return `0`;
103	}
104
105	decode:
106	memset(&lambda[`1`], `0`, nroots * sizeof(lambda[`0`]));
107	lambda[`0`] = `1`;
108
109	if (no_eras > `0`) {
110	/ Init lambda to be the erasure locator polynomial /
111	lambda[`1`] = alpha_to[rs_modnn(rs,
112	prim * (nn - `1` - (eras_pos[`0`] + pad)))];
113	for (i = `1`; i < no_eras; i++) {
114	u = rs_modnn(rs, prim * (nn - `1` - (eras_pos[i] + pad)));
115	for (j = i + `1`; j > `0`; j--) {
116	tmp = index_of[lambda[j - `1`]];
117	if (tmp != nn) {
118	lambda[j] ^=
119	alpha_to[rs_modnn(rs, u + tmp)];
120	}
121	}
122	}
123	}
124
125	for (i = `0`; i < nroots + `1`; i++)
126	b[i] = index_of[lambda[i]];
127
128	/*
129	* Begin Berlekamp-Massey algorithm to determine error+erasure
130	* locator polynomial
131	*/
132	r = no_eras;
133	el = no_eras;
134	while (++r <= nroots) { / r is the step number /
135	/ Compute discrepancy at the r-th step in poly-form /
136	discr_r = `0`;
137	for (i = `0`; i < r; i++) {
138	if ((lambda[i] != `0`) && (s[r - i - `1`] != nn)) {
139	discr_r ^=
140	alpha_to[rs_modnn(rs,
141	index_of[lambda[i]] +
142	s[r - i - `1`])];
143	}
144	}
145	discr_r = index_of[discr_r]; / Index form /
146	if (discr_r == nn) {
147	/ 2 lines below: B(x) <-- xB(x) /*
148	memmove (&b[`1`], b, nroots * sizeof (b[`0`]));
149	b[`0`] = nn;
150	} else {
151	/ 7 lines below: T(x) <-- lambda(x)-discr_rxb(x) /
152	t[`0`] = lambda[`0`];
153	for (i = `0`; i < nroots; i++) {
154	if (b[i] != nn) {
155	t[i + `1`] = lambda[i + `1`] ^
156	alpha_to[rs_modnn(rs, discr_r +
157	b[i])];
158	} else
159	t[i + `1`] = lambda[i + `1`];
160	}
161	if (`2` * el <= r + no_eras - `1`) {
162	el = r + no_eras - el;
163	/*
164	* 2 lines below: B(x) <-- inv(discr_r) *
165	* lambda(x)
166	*/
167	for (i = `0`; i <= nroots; i++) {
168	b[i] = (lambda[i] == `0`) ? nn :
169	rs_modnn(rs, index_of[lambda[i]]
170	- discr_r + nn);
171	}
172	} else {
173	/ 2 lines below: B(x) <-- xB(x) /*
174	memmove(&b[`1`], b, nroots * sizeof(b[`0`]));
175	b[`0`] = nn;
176	}
177	memcpy(lambda, t, (nroots + `1`) * sizeof(t[`0`]));
178	}
179	}
180
181	/ Convert lambda to index form and compute deg(lambda(x)) /
182	deg_lambda = `0`;
183	for (i = `0`; i < nroots + `1`; i++) {
184	lambda[i] = index_of[lambda[i]];
185	if (lambda[i] != nn)
186	deg_lambda = i;
187	}
188
189	if (deg_lambda == `0`) {
190	/*
191	* deg(lambda) is zero even though the syndrome is non-zero
192	* => uncorrectable error detected
193	*/
194	return -EBADMSG;
195	}
196
197	/ Find roots of error+erasure locator polynomial by Chien search /
198	memcpy(&reg[`1`], &lambda[`1`], nroots * sizeof(reg[`0`]));
199	count = `0`; / Number of roots of lambda(x) /
200	for (i = `1`, k = iprim - `1`; i <= nn; i++, k = rs_modnn(rs, k + iprim)) {
201	q = `1`; / lambda[0] is always 0 /
202	for (j = deg_lambda; j > `0`; j--) {
203	if (reg[j] != nn) {
204	reg[j] = rs_modnn(rs, reg[j] + j);
205	q ^= alpha_to[reg[j]];
206	}
207	}
208	if (q != `0`)
209	continue; / Not a root /
210
211	if (k < pad) {
212	/ Impossible error location. Uncorrectable error. /
213	return -EBADMSG;
214	}
215
216	/ store root (index-form) and error location number /
217	root[count] = i;
218	loc[count] = k;
219	/ If we've already found max possible roots,*
220	* abort the search to save time
221	*/
222	if (++count == deg_lambda)
223	break;
224	}
225	if (deg_lambda != count) {
226	/*
227	* deg(lambda) unequal to number of roots => uncorrectable
228	* error detected
229	*/
230	return -EBADMSG;
231	}
232	/*
233	* Compute err+eras evaluator poly omega(x) = s(x)*lambda(x) (modulo
234	* x**nroots). in index form. Also find deg(omega).
235	*/
236	deg_omega = deg_lambda - `1`;
237	for (i = `0`; i <= deg_omega; i++) {
238	tmp = `0`;
239	for (j = i; j >= `0`; j--) {
240	if ((s[i - j] != nn) && (lambda[j] != nn))
241	tmp ^=
242	alpha_to[rs_modnn(rs, s[i - j] + lambda[j])];
243	}
244	omega[i] = index_of[tmp];
245	}
246
247	/*
248	* Compute error values in poly-form. num1 = omega(inv(X(l))), num2 =
249	* inv(X(l))**(fcr-1) and den = lambda_pr(inv(X(l))) all in poly-form
250	* Note: we reuse the buffer for b to store the correction pattern
251	*/
252	num_corrected = `0`;
253	for (j = count - `1`; j >= `0`; j--) {
254	num1 = `0`;
255	for (i = deg_omega; i >= `0`; i--) {
256	if (omega[i] != nn)
257	num1 ^= alpha_to[rs_modnn(rs, omega[i] +
258	i * root[j])];
259	}
260
261	if (num1 == `0`) {
262	/ Nothing to correct at this position /
263	b[j] = `0`;
264	continue;
265	}
266
267	num2 = alpha_to[rs_modnn(rs, root[j] * (fcr - `1`) + nn)];
268	den = `0`;
269
270	/ lambda[i+1] for i even is the formal derivative*
271	* lambda_pr of lambda[i] */
272	for (i = min(deg_lambda, nroots - `1`) & ~`1`; i >= `0`; i -= `2`) {
273	if (lambda[i + `1`] != nn) {
274	den ^= alpha_to[rs_modnn(rs, lambda[i + `1`] +
275	i * root[j])];
276	}
277	}
278
279	b[j] = alpha_to[rs_modnn(rs, index_of[num1] +
280	index_of[num2] +
281	nn - index_of[den])];
282	num_corrected++;
283	}
284
285	/*
286	* We compute the syndrome of the 'error' and check that it matches
287	* the syndrome of the received word
288	*/
289	for (i = `0`; i < nroots; i++) {
290	tmp = `0`;
291	for (j = `0`; j < count; j++) {
292	if (b[j] == `0`)
293	continue;
294
295	k = (fcr + i) * prim * (nn-loc[j]-`1`);
296	tmp ^= alpha_to[rs_modnn(rs, index_of[b[j]] + k)];
297	}
298
299	if (tmp != alpha_to[s[i]])
300	return -EBADMSG;
301	}
302
303	/*
304	* Store the error correction pattern, if a
305	* correction buffer is available
306	*/
307	if (corr && eras_pos) {
308	j = `0`;
309	for (i = `0`; i < count; i++) {
310	if (b[i]) {
311	corr[j] = b[i];
312	eras_pos[j++] = loc[i] - pad;
313	}
314	}
315	} else if (data && par) {
316	/ Apply error to data and parity /
317	for (i = `0`; i < count; i++) {
318	if (loc[i] < (nn - nroots))
319	data[loc[i] - pad] ^= b[i];
320	else
321	par[loc[i] - pad - len] ^= b[i];
322	}
323	}
324
325	return num_corrected;
326	}
327

source code of linux/lib/reed_solomon/decode_rs.c