1 files changed, 174 insertions, 174 deletions

diff --git a/src/flash/nand_ecc_kw.c b/src/flash/nand_ecc_kw.c
index ecc7adc2..a7fae626 100644
--- a/src/flash/nand_ecc_kw.c
+++ b/src/flash/nand_ecc_kw.c
@@ -1,174 +1,174 @@
-/*

- * Reed-Solomon ECC handling for the Marvell Kirkwood SOC

- * Copyright (C) 2009 Marvell Semiconductor, Inc.

- *

- * Authors: Lennert Buytenhek <buytenh@wantstofly.org>

- *          Nicolas Pitre <nico@cam.org>

- *

- * This file 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 or (at your option) any

- * later version.

- *

- * This file 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.

- */

-

-#ifdef HAVE_CONFIG_H

-#include "config.h"

-#endif

-

-#include <sys/types.h>

-#include "nand.h"

-

-

-/*****************************************************************************

- * Arithmetic in GF(2^10) ("F") modulo x^10 + x^3 + 1.

- *

- * For multiplication, a discrete log/exponent table is used, with

- * primitive element x (F is a primitive field, so x is primitive).

- */

-#define MODPOLY		0x409		/* x^10 + x^3 + 1 in binary */

-

-/*

- * Maps an integer a [0..1022] to a polynomial b = gf_exp[a] in

- * GF(2^10) mod x^10 + x^3 + 1 such that b = x ^ a.  There's two

- * identical copies of this array back-to-back so that we can save

- * the mod 1023 operation when doing a GF multiplication.

- */

-static uint16_t gf_exp[1023 + 1023];

-

-/*

- * Maps a polynomial b in GF(2^10) mod x^10 + x^3 + 1 to an index

- * a = gf_log[b] in [0..1022] such that b = x ^ a.

- */

-static uint16_t gf_log[1024];

-

-static void gf_build_log_exp_table(void)

-{

-	int i;

-	int p_i;

-

-	/*

-	 * p_i = x ^ i

-	 *

-	 * Initialise to 1 for i = 0.

-	 */

-	p_i = 1;

-

-	for (i = 0; i < 1023; i++) {

-		gf_exp[i] = p_i;

-		gf_exp[i + 1023] = p_i;

-		gf_log[p_i] = i;

-

-		/*

-		 * p_i = p_i * x

-		 */

-		p_i <<= 1;

-		if (p_i & (1 << 10))

-			p_i ^= MODPOLY;

-	}

-}

-

-

-/*****************************************************************************

- * Reed-Solomon code

- *

- * This implements a (1023,1015) Reed-Solomon ECC code over GF(2^10)

- * mod x^10 + x^3 + 1, shortened to (520,512).  The ECC data consists

- * of 8 10-bit symbols, or 10 8-bit bytes.

- *

- * Given 512 bytes of data, computes 10 bytes of ECC.

- *

- * This is done by converting the 512 bytes to 512 10-bit symbols

- * (elements of F), interpreting those symbols as a polynomial in F[X]

- * by taking symbol 0 as the coefficient of X^8 and symbol 511 as the

- * coefficient of X^519, and calculating the residue of that polynomial

- * divided by the generator polynomial, which gives us the 8 ECC symbols

- * as the remainder.  Finally, we convert the 8 10-bit ECC symbols to 10

- * 8-bit bytes.

- *

- * The generator polynomial is hardcoded, as that is faster, but it

- * can be computed by taking the primitive element a = x (in F), and

- * constructing a polynomial in F[X] with roots a, a^2, a^3, ..., a^8

- * by multiplying the minimal polynomials for those roots (which are

- * just 'x - a^i' for each i).

- *

- * Note: due to unfortunate circumstances, the bootrom in the Kirkwood SOC

- * expects the ECC to be computed backward, i.e. from the last byte down

- * to the first one.

- */

-int nand_calculate_ecc_kw(struct nand_device_s *device, const u8 *data, u8 *ecc)

-{

-	unsigned int r7, r6, r5, r4, r3, r2, r1, r0;

-	int i;

-	static int tables_initialized = 0;

-

-	if (!tables_initialized) {

-		gf_build_log_exp_table();

-		tables_initialized = 1;

-	}

-

-	/*

-	 * Load bytes 504..511 of the data into r.

-	 */

-	r0 = data[504];

-	r1 = data[505];

-	r2 = data[506];

-	r3 = data[507];

-	r4 = data[508];

-	r5 = data[509];

-	r6 = data[510];

-	r7 = data[511];

-

-

-	/*

-	 * Shift bytes 503..0 (in that order) into r0, followed

-	 * by eight zero bytes, while reducing the polynomial by the

-	 * generator polynomial in every step.

-	 */

-	for (i = 503; i >= -8; i--) {

-		unsigned int d;

-

-		d = 0;

-		if (i >= 0)

-			d = data[i];

-

-		if (r7) {

-			u16 *t = gf_exp + gf_log[r7];

-

-			r7 = r6 ^ t[0x21c];

-			r6 = r5 ^ t[0x181];

-			r5 = r4 ^ t[0x18e];

-			r4 = r3 ^ t[0x25f];

-			r3 = r2 ^ t[0x197];

-			r2 = r1 ^ t[0x193];

-			r1 = r0 ^ t[0x237];

-			r0 = d  ^ t[0x024];

-		} else {

-			r7 = r6;

-			r6 = r5;

-			r5 = r4;

-			r4 = r3;

-			r3 = r2;

-			r2 = r1;

-			r1 = r0;

-			r0 = d;

-		}

-	}

-

-	ecc[0] = r0;

-	ecc[1] = (r0 >> 8) | (r1 << 2);

-	ecc[2] = (r1 >> 6) | (r2 << 4);

-	ecc[3] = (r2 >> 4) | (r3 << 6);

-	ecc[4] = (r3 >> 2);

-	ecc[5] = r4;

-	ecc[6] = (r4 >> 8) | (r5 << 2);

-	ecc[7] = (r5 >> 6) | (r6 << 4);

-	ecc[8] = (r6 >> 4) | (r7 << 6);

-	ecc[9] = (r7 >> 2);

-

-	return 0;

-}

+/*
+ * Reed-Solomon ECC handling for the Marvell Kirkwood SOC
+ * Copyright (C) 2009 Marvell Semiconductor, Inc.
+ *
+ * Authors: Lennert Buytenhek <buytenh@wantstofly.org>
+ *          Nicolas Pitre <nico@cam.org>
+ *
+ * This file 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 or (at your option) any
+ * later version.
+ *
+ * This file 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.
+ */
+
+#ifdef HAVE_CONFIG_H
+#include "config.h"
+#endif
+
+#include <sys/types.h>
+#include "nand.h"
+
+
+/*****************************************************************************
+ * Arithmetic in GF(2^10) ("F") modulo x^10 + x^3 + 1.
+ *
+ * For multiplication, a discrete log/exponent table is used, with
+ * primitive element x (F is a primitive field, so x is primitive).
+ */
+#define MODPOLY		0x409		/* x^10 + x^3 + 1 in binary */
+
+/*
+ * Maps an integer a [0..1022] to a polynomial b = gf_exp[a] in
+ * GF(2^10) mod x^10 + x^3 + 1 such that b = x ^ a.  There's two
+ * identical copies of this array back-to-back so that we can save
+ * the mod 1023 operation when doing a GF multiplication.
+ */
+static uint16_t gf_exp[1023 + 1023];
+
+/*
+ * Maps a polynomial b in GF(2^10) mod x^10 + x^3 + 1 to an index
+ * a = gf_log[b] in [0..1022] such that b = x ^ a.
+ */
+static uint16_t gf_log[1024];
+
+static void gf_build_log_exp_table(void)
+{
+	int i;
+	int p_i;
+
+	/*
+	 * p_i = x ^ i
+	 *
+	 * Initialise to 1 for i = 0.
+	 */
+	p_i = 1;
+
+	for (i = 0; i < 1023; i++) {
+		gf_exp[i] = p_i;
+		gf_exp[i + 1023] = p_i;
+		gf_log[p_i] = i;
+
+		/*
+		 * p_i = p_i * x
+		 */
+		p_i <<= 1;
+		if (p_i & (1 << 10))
+			p_i ^= MODPOLY;
+	}
+}
+
+
+/*****************************************************************************
+ * Reed-Solomon code
+ *
+ * This implements a (1023,1015) Reed-Solomon ECC code over GF(2^10)
+ * mod x^10 + x^3 + 1, shortened to (520,512).  The ECC data consists
+ * of 8 10-bit symbols, or 10 8-bit bytes.
+ *
+ * Given 512 bytes of data, computes 10 bytes of ECC.
+ *
+ * This is done by converting the 512 bytes to 512 10-bit symbols
+ * (elements of F), interpreting those symbols as a polynomial in F[X]
+ * by taking symbol 0 as the coefficient of X^8 and symbol 511 as the
+ * coefficient of X^519, and calculating the residue of that polynomial
+ * divided by the generator polynomial, which gives us the 8 ECC symbols
+ * as the remainder.  Finally, we convert the 8 10-bit ECC symbols to 10
+ * 8-bit bytes.
+ *
+ * The generator polynomial is hardcoded, as that is faster, but it
+ * can be computed by taking the primitive element a = x (in F), and
+ * constructing a polynomial in F[X] with roots a, a^2, a^3, ..., a^8
+ * by multiplying the minimal polynomials for those roots (which are
+ * just 'x - a^i' for each i).
+ *
+ * Note: due to unfortunate circumstances, the bootrom in the Kirkwood SOC
+ * expects the ECC to be computed backward, i.e. from the last byte down
+ * to the first one.
+ */
+int nand_calculate_ecc_kw(struct nand_device_s *device, const u8 *data, u8 *ecc)
+{
+	unsigned int r7, r6, r5, r4, r3, r2, r1, r0;
+	int i;
+	static int tables_initialized = 0;
+
+	if (!tables_initialized) {
+		gf_build_log_exp_table();
+		tables_initialized = 1;
+	}
+
+	/*
+	 * Load bytes 504..511 of the data into r.
+	 */
+	r0 = data[504];
+	r1 = data[505];
+	r2 = data[506];
+	r3 = data[507];
+	r4 = data[508];
+	r5 = data[509];
+	r6 = data[510];
+	r7 = data[511];
+
+
+	/*
+	 * Shift bytes 503..0 (in that order) into r0, followed
+	 * by eight zero bytes, while reducing the polynomial by the
+	 * generator polynomial in every step.
+	 */
+	for (i = 503; i >= -8; i--) {
+		unsigned int d;
+
+		d = 0;
+		if (i >= 0)
+			d = data[i];
+
+		if (r7) {
+			u16 *t = gf_exp + gf_log[r7];
+
+			r7 = r6 ^ t[0x21c];
+			r6 = r5 ^ t[0x181];
+			r5 = r4 ^ t[0x18e];
+			r4 = r3 ^ t[0x25f];
+			r3 = r2 ^ t[0x197];
+			r2 = r1 ^ t[0x193];
+			r1 = r0 ^ t[0x237];
+			r0 = d  ^ t[0x024];
+		} else {
+			r7 = r6;
+			r6 = r5;
+			r5 = r4;
+			r4 = r3;
+			r3 = r2;
+			r2 = r1;
+			r1 = r0;
+			r0 = d;
+		}
+	}
+
+	ecc[0] = r0;
+	ecc[1] = (r0 >> 8) | (r1 << 2);
+	ecc[2] = (r1 >> 6) | (r2 << 4);
+	ecc[3] = (r2 >> 4) | (r3 << 6);
+	ecc[4] = (r3 >> 2);
+	ecc[5] = r4;
+	ecc[6] = (r4 >> 8) | (r5 << 2);
+	ecc[7] = (r5 >> 6) | (r6 << 4);
+	ecc[8] = (r6 >> 4) | (r7 << 6);
+	ecc[9] = (r7 >> 2);
+
+	return 0;
+}