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317 lines
9.3 KiB
C++
317 lines
9.3 KiB
C++
#ifndef LEANSDR_RS_H
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#define LEANSDR_RS_H
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#include "leansdr/math.h"
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#define DEBUG_RS 0
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namespace leansdr
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{
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// Finite group GF(2^N).
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// GF(2) is the ring ({0,1},+,*).
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// GF(2)[X] is the ring of polynomials with coefficients in GF(2).
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// P(X) is an irreducible polynomial of GF(2)[X].
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// N is the degree of P(x).
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// P is the bitfield representation of P(X), with degree 0 at LSB.
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// GF(2)[X]/(P) is GF(2)[X] modulo P(X).
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// (GF(2)[X]/(P), +) is a group with 2^N elements.
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// (GF(2)[X]/(P)*, *) is a group with 2^N-1 elements.
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// (GF(2)[X]/(P), +, *) is a field with 2^N elements, noted GF(2^N).
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// Te is a C++ integer type for representing elements of GF(2^N).
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// "0" is 0
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// "1" is 1
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// "2" is X
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// "3" is X+1
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// "4" is X^2
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// Tp is a C++ integer type for representing P(X) (1 bit larger than Te).
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// ALPHA is a primitive element of GF(2^N). Usually "2"=[X] is chosen.
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template<typename Te, typename Tp, Tp P, int N, Te ALPHA>
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struct gf2x_p
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{
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gf2x_p()
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{
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if (ALPHA != 2)
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{
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fail("gf2x_p::gf2x_p", "alpha!=2 not implemented");
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return;
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}
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// Precompute log and exp tables.
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Tp alpha_i = 1;
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for (Tp i = 0; i < (1 << N); ++i)
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{
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lut_exp[i] = alpha_i;
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lut_exp[((1 << N) - 1) + i] = alpha_i;
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lut_log[alpha_i] = i;
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alpha_i <<= 1; // Multiply by alpha=[X] i.e. increase degrees
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if (alpha_i & (1 << N))
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alpha_i ^= P; // Modulo P iteratively
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}
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}
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static const Te alpha = ALPHA;
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inline Te add(Te x, Te y)
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{
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return x ^ y;
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} // Addition modulo 2
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inline Te sub(Te x, Te y)
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{
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return x ^ y;
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} // Subtraction modulo 2
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inline Te mul(Te x, Te y)
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{
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if (!x || !y)
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return 0;
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return lut_exp[lut_log[x] + lut_log[y]];
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}
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inline Te div(Te x, Te y)
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{
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//if ( ! y ) fail("div"); // TODO
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if (!x)
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return 0;
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return lut_exp[lut_log[x] + ((1 << N) - 1) - lut_log[y]];
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}
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inline Te inv(Te x)
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{
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// if ( ! x ) fail("inv");
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return lut_exp[((1 << N) - 1) - lut_log[x]];
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}
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inline Te exp(Te x)
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{
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return lut_exp[x];
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}
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inline Te log(Te x)
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{
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return lut_log[x];
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}
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private:
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Te lut_exp[(1 << N) * 2]; // Wrap to avoid indexing modulo 2^N-1
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Te lut_log[1 << N];
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};
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// Reed-Solomon for RS(204,188) shortened from RS(255,239).
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struct rs_engine
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{
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// EN 300 421, section 4.4.2, Field Generator Polynomial
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// p(X) = X^8 + X^4 + X^3 + X^2 + 1
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gf2x_p<unsigned char, unsigned short, 0x11d, 8, 2> gf;
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u8 G[17]; // { G_16, ..., G_0 }
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rs_engine()
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{
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// EN 300 421, section 4.4.2, Code Generator Polynomial
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// G(X) = (X-alpha^0)*...*(X-alpha^15)
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for (int i = 0; i <= 16; ++i)
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G[i] = (i == 16) ? 1 : 0; // Init G=1
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for (int d = 0; d < 16; ++d)
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{
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// Multiply by (X-alpha^d)
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// G := X*G - alpha^d*G
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for (int i = 0; i <= 16; ++i)
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G[i] = gf.sub((i == 16) ? 0 : G[i + 1], gf.mul(gf.exp(d), G[i]));
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}
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#if DEBUG_RS
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fprintf(stderr, "RS generator:");
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for ( int i=0; i<=16; ++i ) fprintf(stderr, " %02x", G[i]);
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fprintf(stderr, "\n");
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#endif
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}
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// RS-encoded messages are interpreted as coefficients in
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// GF(256) of a polynomial P.
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// The syndromes are synd[i] = P(alpha^i).
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// By convention coefficients are listed by decreasing degree here,
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// so we can evaluate syndromes of the shortened code without
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// prepending with 51 zeroes.
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bool syndromes(const u8 *poly, u8 *synd)
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{
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bool corrupted = false;
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for (int i = 0; i < 16; ++i)
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{
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synd[i] = eval_poly_rev(poly, 204, gf.exp(i));
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if (synd[i])
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corrupted = true;
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}
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return corrupted;
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}
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u8 eval_poly_rev(const u8 *poly, int n, u8 x)
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{
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// poly[0]*x^(n-1) + .. + poly[n-1]*x^0 with Hörner method.
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u8 acc = 0;
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for (int i = 0; i < n; ++i)
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acc = gf.add(gf.mul(acc, x), poly[i]);
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return acc;
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}
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// Evaluation with coefficients listed by increasing degree.
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u8 eval_poly(const u8 *poly, int deg, u8 x)
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{
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// poly[0]*x^0 + .. + poly[deg]*x^deg with Hörner method.
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u8 acc = 0;
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for (; deg >= 0; --deg)
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acc = gf.add(gf.mul(acc, x), poly[deg]);
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return acc;
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}
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// Append parity symbols
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void encode(u8 msg[204])
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{
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// TBD Avoid copying
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u8 p[204];
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memcpy(p, msg, 188);
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memset(p + 188, 0, 16);
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// p = msg*X^16
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#if DEBUG_RS
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fprintf(stderr, "uncoded:");
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for ( int i=0; i<204; ++i ) fprintf(stderr, " %d", p[i]);
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fprintf(stderr, "\n");
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#endif
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// Compute remainder modulo G
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for (int d = 0; d < 188; ++d)
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{
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// Clear monomial of degree d
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if (!p[d])
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continue;
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u8 k = gf.div(p[d], G[0]);
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// p(X) := p(X) - k*G(X)*X^(188-d)
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for (int i = 0; i <= 16; ++i)
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p[d + i] = gf.sub(p[d + i], gf.mul(k, G[i]));
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}
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#if DEBUG_RS
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fprintf(stderr, "coded:");
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for ( int i=0; i<204; ++i ) fprintf(stderr, " %d", p[i]);
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fprintf(stderr, "\n");
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#endif
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memcpy(msg + 188, p + 188, 16);
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}
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// Try to fix errors in pout[].
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// If pin[] is provided, errors will be fixed in the original
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// message too and syndromes will be updated.
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bool correct(u8 synd[16], u8 pout[188], u8 pin[204] = NULL, int *bits_corrected = NULL)
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{
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// Berlekamp - Massey
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// http://en.wikipedia.org/wiki/Berlekamp%E2%80%93Massey_algorithm#Code_sample
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u8 C[16] =
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{ 1, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0 }; // Max degree is L
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u8 B[16] =
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{ 1, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0 };
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int L = 0;
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int m = 1;
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u8 b = 1;
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for (int n = 0; n < 16; ++n)
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{
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u8 d = synd[n];
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for (int i = 1; i <= L; ++i)
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d ^= gf.mul(C[i], synd[n - i]);
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if (!d)
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{
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++m;
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}
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else if (2 * L <= n)
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{
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u8 T[16];
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memcpy(T, C, sizeof(T));
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for (int i = 0; i < 16 - m; ++i)
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C[m + i] ^= gf.mul(d, gf.mul(gf.inv(b), B[i]));
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L = n + 1 - L;
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memcpy(B, T, sizeof(B));
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b = d;
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m = 1;
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}
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else
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{
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for (int i = 0; i < 16 - m; ++i)
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C[m + i] ^= gf.mul(d, gf.mul(gf.inv(b), B[i]));
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++m;
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}
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}
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// L is the number of errors
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// C of degree L is now the error locator polynomial (Lambda)
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#if DEBUG_RS
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fprintf(stderr, "[L=%d C=",L);
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for ( int i=0; i<16; ++i ) fprintf(stderr, " %d", C[i]);
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fprintf(stderr, "]\n");
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fprintf(stderr, "[S=");
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for ( int i=0; i<16; ++i ) fprintf(stderr, " %d", synd[i]);
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fprintf(stderr, "]\n");
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#endif
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// Forney
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// http://en.wikipedia.org/wiki/Forney_algorithm (2t=16)
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// Compute Omega
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u8 omega[16];
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memset(omega, 0, sizeof(omega));
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// TODO loops
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for (int i = 0; i < 16; ++i)
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for (int j = 0; j < 16; ++j)
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if (i + j < 16)
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omega[i + j] ^= gf.mul(synd[i], C[j]);
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#if DEBUG_RS
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fprintf(stderr, "omega=");
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for ( int i=0; i<16; ++i ) fprintf(stderr, " %d", omega[i]);
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fprintf(stderr, "\n");
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#endif
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// Compute Lambda'
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u8 Cprime[15];
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for (int i = 0; i < 15; ++i)
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Cprime[i] = (i & 1) ? 0 : C[i + 1];
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#if DEBUG_RS
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fprintf(stderr, "Cprime=");
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for ( int i=0; i<15; ++i ) fprintf(stderr, " %d", Cprime[i]);
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fprintf(stderr, "\n");
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#endif
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// Find zeroes of C by exhaustive search?
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// TODO Chien method
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int roots_found = 0;
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for (int i = 0; i < 255; ++i)
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{
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u8 r = gf.exp(i); // Candidate root alpha^0..alpha^254
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u8 v = eval_poly(C, L, r);
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if (!v)
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{
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// r is a root X_k^-1 of the error locator polynomial.
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u8 xk = gf.inv(r);
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int loc = (255 - i) % 255; // == log(xk)
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#if DEBUG_RS
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fprintf(stderr, "found root=%d, inv=%d, loc=%d\n", r, xk, loc);
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#endif
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if (loc < 204)
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{
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// Evaluate e_k
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u8 num = gf.mul(xk, eval_poly(omega, L, r));
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u8 den = eval_poly(Cprime, 14, r);
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u8 e = gf.div(num, den);
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// Subtract e from coefficient of degree loc.
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// Note: Coeffients listed by decreasing degree in pin[] and pout[].
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if (bits_corrected)
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*bits_corrected += hamming_weight(e);
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if (loc >= 16)
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pout[203 - loc] ^= e;
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if (pin)
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pin[203 - loc] ^= e;
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}
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if (++roots_found == L)
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break;
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}
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}
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if (pin)
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return syndromes(pin, synd);
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else
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return false;
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}
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};
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} // namespace
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#endif // LEANSDR_RS_H
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