void mul_aux(mat_zz_pE& X, const mat_zz_pE& A, const mat_zz_pE& B) { long n = A.NumRows(); long l = A.NumCols(); long m = B.NumCols(); if (l != B.NumRows()) Error("matrix mul: dimension mismatch"); X.SetDims(n, m); long i, j, k; zz_pX acc, tmp; for (i = 1; i <= n; i++) { for (j = 1; j <= m; j++) { clear(acc); for(k = 1; k <= l; k++) { mul(tmp, rep(A(i,k)), rep(B(k,j))); add(acc, acc, tmp); } conv(X(i,j), acc); } } }
void sub(mat_zz_pE& X, const mat_zz_pE& A, const mat_zz_pE& B) { long n = A.NumRows(); long m = A.NumCols(); if (B.NumRows() != n || B.NumCols() != m) Error("matrix sub: dimension mismatch"); X.SetDims(n, m); long i, j; for (i = 1; i <= n; i++) for (j = 1; j <= m; j++) sub(X(i,j), A(i,j), B(i,j)); }
void transpose(mat_zz_pE& X, const mat_zz_pE& A) { long n = A.NumRows(); long m = A.NumCols(); long i, j; if (&X == & A) { if (n == m) for (i = 1; i <= n; i++) for (j = i+1; j <= n; j++) swap(X(i, j), X(j, i)); else { mat_zz_pE tmp; tmp.SetDims(m, n); for (i = 1; i <= n; i++) for (j = 1; j <= m; j++) tmp(j, i) = A(i, j); X.kill(); X = tmp; } } else { X.SetDims(m, n); for (i = 1; i <= n; i++) for (j = 1; j <= m; j++) X(j, i) = A(i, j); } }
void power(mat_zz_pE& X, const mat_zz_pE& A, const ZZ& e) { if (A.NumRows() != A.NumCols()) Error("power: non-square matrix"); if (e == 0) { ident(X, A.NumRows()); return; } mat_zz_pE T1, T2; long i, k; k = NumBits(e); T1 = A; for (i = k-2; i >= 0; i--) { sqr(T2, T1); if (bit(e, i)) mul(T1, T2, A); else T1 = T2; } if (e < 0) inv(X, T1); else X = T1; }
NTL_START_IMPL void add(mat_zz_pE& X, const mat_zz_pE& A, const mat_zz_pE& B) { long n = A.NumRows(); long m = A.NumCols(); if (B.NumRows() != n || B.NumCols() != m) LogicError("matrix add: dimension mismatch"); X.SetDims(n, m); long i, j; for (i = 1; i <= n; i++) for (j = 1; j <= m; j++) add(X(i,j), A(i,j), B(i,j)); }
void negate(mat_zz_pE& X, const mat_zz_pE& A) { long n = A.NumRows(); long m = A.NumCols(); X.SetDims(n, m); long i, j; for (i = 1; i <= n; i++) for (j = 1; j <= m; j++) negate(X(i,j), A(i,j)); }
void mul(mat_zz_pE& X, const mat_zz_pE& A, const zz_pE& b_in) { zz_pE b = b_in; long n = A.NumRows(); long m = A.NumCols(); X.SetDims(n, m); long i, j; for (i = 0; i < n; i++) for (j = 0; j < m; j++) mul(X[i][j], A[i][j], b); }
void mul(mat_zz_pE& X, const mat_zz_pE& A, long b_in) { newNTL_zz_pRegister(b); b = b_in; long n = A.NumRows(); long m = A.NumCols(); X.SetDims(n, m); long i, j; for (i = 0; i < n; i++) for (j = 0; j < m; j++) mul(X[i][j], A[i][j], b); }
void convert(mat_zz_pE& X, const vector< vector<ZZX> >& A) { long n = A.size(); if (n == 0) { long m = X.NumCols(); X.SetDims(0, m); return; } long m = A[0].size(); X.SetDims(n, m); for (long i = 0; i < n; i++) convert(X[i], A[i]); }
long IsDiag(const mat_zz_pE& A, long n, const zz_pE& d) { if (A.NumRows() != n || A.NumCols() != n) return 0; long i, j; for (i = 1; i <= n; i++) for (j = 1; j <= n; j++) if (i != j) { if (!IsZero(A(i, j))) return 0; } else { if (A(i, j) != d) return 0; } return 1; }
namespaceanon void mul_aux(vec_zz_pE& x, const mat_zz_pE& A, const vec_zz_pE& b) { long n = A.NumRows(); long l = A.NumCols(); if (l != b.length()) Error("matrix mul: dimension mismatch"); x.SetLength(n); long i, k; zz_pX acc, tmp; for (i = 1; i <= n; i++) { clear(acc); for (k = 1; k <= l; k++) { mul(tmp, rep(A(i,k)), rep(b(k))); add(acc, acc, tmp); } conv(x(i), acc); } }
namespaceanon void mul_aux(vec_zz_pE& x, const vec_zz_pE& a, const mat_zz_pE& B) { long n = B.NumRows(); long l = B.NumCols(); if (n != a.length()) Error("matrix mul: dimension mismatch"); x.SetLength(l); long i, k; zz_pX acc, tmp; for (i = 1; i <= l; i++) { clear(acc); for (k = 1; k <= n; k++) { mul(tmp, rep(a(k)), rep(B(k,i))); add(acc, acc, tmp); } conv(x(i), acc); } }
void kernel(mat_zz_pE& X, const mat_zz_pE& A) { long m = A.NumRows(); long n = A.NumCols(); mat_zz_pE M; long r; transpose(M, A); r = gauss(M); X.SetDims(m-r, m); long i, j, k, s; zz_pX t1, t2; zz_pE T3; vec_long D; D.SetLength(m); for (j = 0; j < m; j++) D[j] = -1; vec_zz_pE inverses; inverses.SetLength(m); j = -1; for (i = 0; i < r; i++) { do { j++; } while (IsZero(M[i][j])); D[j] = i; inv(inverses[j], M[i][j]); } for (k = 0; k < m-r; k++) { vec_zz_pE& v = X[k]; long pos = 0; for (j = m-1; j >= 0; j--) { if (D[j] == -1) { if (pos == k) set(v[j]); else clear(v[j]); pos++; } else { i = D[j]; clear(t1); for (s = j+1; s < m; s++) { mul(t2, rep(v[s]), rep(M[i][s])); add(t1, t1, t2); } conv(T3, t1); mul(T3, T3, inverses[j]); negate(v[j], T3); } } } }
long gauss(mat_zz_pE& M) { return gauss(M, M.NumCols()); }
// prime power solver // zz_p::modulus() is assumed to be p^r, for p prime, r >= 1 // A is an n x n matrix, b is a length n (row) vector, // and a solution for the matrix-vector equation x A = b is found. // If A is not inverible mod p, then error is raised. void ppsolve(vec_zz_pE& x, const mat_zz_pE& A, const vec_zz_pE& b, long p, long r) { if (r == 1) { zz_pE det; solve(det, x, A, b); if (det == 0) Error("ppsolve: matrix not invertible"); return; } long n = A.NumRows(); if (n != A.NumCols()) Error("ppsolve: matrix not square"); if (n == 0) Error("ppsolve: matrix of dimension 0"); zz_pContext pr_context; pr_context.save(); zz_pEContext prE_context; prE_context.save(); zz_pX G = zz_pE::modulus(); ZZX GG = to_ZZX(G); vector< vector<ZZX> > AA; convert(AA, A); vector<ZZX> bb; convert(bb, b); zz_pContext p_context(p); p_context.restore(); zz_pX G1 = to_zz_pX(GG); zz_pEContext pE_context(G1); pE_context.restore(); // we are now working mod p... // invert A mod p mat_zz_pE A1; convert(A1, AA); mat_zz_pE I1; zz_pE det; inv(det, I1, A1); if (det == 0) { Error("ppsolve: matrix not invertible"); } vec_zz_pE b1; convert(b1, bb); vec_zz_pE y1; y1 = b1 * I1; vector<ZZX> yy; convert(yy, y1); // yy is a solution mod p for (long k = 1; k < r; k++) { // lift solution yy mod p^k to a solution mod p^{k+1} pr_context.restore(); prE_context.restore(); // we are now working mod p^r vec_zz_pE d, y; convert(y, yy); d = b - y * A; vector<ZZX> dd; convert(dd, d); long pk = power_long(p, k); vector<ZZX> ee; div(ee, dd, pk); p_context.restore(); pE_context.restore(); // we are now working mod p vec_zz_pE e1; convert(e1, ee); vec_zz_pE z1; z1 = e1 * I1; vector<ZZX> zz, ww; convert(zz, z1); mul(ww, zz, pk); add(yy, yy, ww); } pr_context.restore(); prE_context.restore(); convert(x, yy); assert(x*A == b); }
void inv(zz_pE& d, mat_zz_pE& X, const mat_zz_pE& A) { long n = A.NumRows(); if (A.NumCols() != n) Error("inv: nonsquare matrix"); if (n == 0) { set(d); X.SetDims(0, 0); return; } long i, j, k, pos; zz_pX t1, t2; zz_pX *x, *y; const zz_pXModulus& p = zz_pE::modulus(); vec_zz_pX *M = newNTL_NEW_OP vec_zz_pX[n]; for (i = 0; i < n; i++) { M[i].SetLength(2*n); for (j = 0; j < n; j++) { M[i][j].rep.SetMaxLength(2*deg(p)-1); M[i][j] = rep(A[i][j]); M[i][n+j].rep.SetMaxLength(2*deg(p)-1); clear(M[i][n+j]); } set(M[i][n+i]); } zz_pX det; set(det); for (k = 0; k < n; k++) { pos = -1; for (i = k; i < n; i++) { rem(t1, M[i][k], p); M[i][k] = t1; if (pos == -1 && !IsZero(t1)) { pos = i; } } if (pos != -1) { if (k != pos) { swap(M[pos], M[k]); negate(det, det); } MulMod(det, det, M[k][k], p); // make M[k, k] == -1 mod p, and make row k reduced InvMod(t1, M[k][k], p); negate(t1, t1); for (j = k+1; j < 2*n; j++) { rem(t2, M[k][j], p); MulMod(M[k][j], t2, t1, p); } for (i = k+1; i < n; i++) { // M[i] = M[i] + M[k]*M[i,k] t1 = M[i][k]; // this is already reduced x = M[i].elts() + (k+1); y = M[k].elts() + (k+1); for (j = k+1; j < 2*n; j++, x++, y++) { // *x = *x + (*y)*t1 mul(t2, *y, t1); add(*x, *x, t2); } } } else { clear(d); goto done; } } X.SetDims(n, n); for (k = 0; k < n; k++) { for (i = n-1; i >= 0; i--) { clear(t1); for (j = i+1; j < n; j++) { mul(t2, rep(X[j][k]), M[i][j]); add(t1, t1, t2); } sub(t1, t1, M[i][n+k]); conv(X[i][k], t1); } } conv(d, det); done: delete[] M; }
void determinant(zz_pE& d, const mat_zz_pE& M_in) { long k, n; long i, j; long pos; zz_pX t1, t2; zz_pX *x, *y; const zz_pXModulus& p = zz_pE::modulus(); n = M_in.NumRows(); if (M_in.NumCols() != n) Error("determinant: nonsquare matrix"); if (n == 0) { set(d); return; } vec_zz_pX *M = newNTL_NEW_OP vec_zz_pX[n]; for (i = 0; i < n; i++) { M[i].SetLength(n); for (j = 0; j < n; j++) { M[i][j].rep.SetMaxLength(2*deg(p)-1); M[i][j] = rep(M_in[i][j]); } } zz_pX det; set(det); for (k = 0; k < n; k++) { pos = -1; for (i = k; i < n; i++) { rem(t1, M[i][k], p); M[i][k] = t1; if (pos == -1 && !IsZero(t1)) pos = i; } if (pos != -1) { if (k != pos) { swap(M[pos], M[k]); negate(det, det); } MulMod(det, det, M[k][k], p); // make M[k, k] == -1 mod p, and make row k reduced InvMod(t1, M[k][k], p); negate(t1, t1); for (j = k+1; j < n; j++) { rem(t2, M[k][j], p); MulMod(M[k][j], t2, t1, p); } for (i = k+1; i < n; i++) { // M[i] = M[i] + M[k]*M[i,k] t1 = M[i][k]; // this is already reduced x = M[i].elts() + (k+1); y = M[k].elts() + (k+1); for (j = k+1; j < n; j++, x++, y++) { // *x = *x + (*y)*t1 mul(t2, *y, t1); add(*x, *x, t2); } } } else { clear(d); goto done; } } conv(d, det); done: delete[] M; }
long gauss(mat_zz_pE& M_in, long w) { long k, l; long i, j; long pos; zz_pX t1, t2, t3; zz_pX *x, *y; long n = M_in.NumRows(); long m = M_in.NumCols(); if (w < 0 || w > m) Error("gauss: bad args"); const zz_pXModulus& p = zz_pE::modulus(); vec_zz_pX *M = newNTL_NEW_OP vec_zz_pX[n]; for (i = 0; i < n; i++) { M[i].SetLength(m); for (j = 0; j < m; j++) { M[i][j].rep.SetMaxLength(2*deg(p)-1); M[i][j] = rep(M_in[i][j]); } } l = 0; for (k = 0; k < w && l < n; k++) { pos = -1; for (i = l; i < n; i++) { rem(t1, M[i][k], p); M[i][k] = t1; if (pos == -1 && !IsZero(t1)) { pos = i; } } if (pos != -1) { swap(M[pos], M[l]); InvMod(t3, M[l][k], p); negate(t3, t3); for (j = k+1; j < m; j++) { rem(M[l][j], M[l][j], p); } for (i = l+1; i < n; i++) { // M[i] = M[i] + M[l]*M[i,k]*t3 MulMod(t1, M[i][k], t3, p); clear(M[i][k]); x = M[i].elts() + (k+1); y = M[l].elts() + (k+1); for (j = k+1; j < m; j++, x++, y++) { // *x = *x + (*y)*t1 mul(t2, *y, t1); add(t2, t2, *x); *x = t2; } } l++; } } for (i = 0; i < n; i++) for (j = 0; j < m; j++) conv(M_in[i][j], M[i][j]); delete [] M; return l; }
static void solve_impl(zz_pE& d, vec_zz_pE& X, const mat_zz_pE& A, const vec_zz_pE& b, bool trans) { long n = A.NumRows(); if (A.NumCols() != n) LogicError("solve: nonsquare matrix"); if (b.length() != n) LogicError("solve: dimension mismatch"); if (n == 0) { set(d); X.SetLength(0); return; } long i, j, k, pos; zz_pX t1, t2; zz_pX *x, *y; const zz_pXModulus& p = zz_pE::modulus(); UniqueArray<vec_zz_pX> M_store; M_store.SetLength(n); vec_zz_pX *M = M_store.get(); for (i = 0; i < n; i++) { M[i].SetLength(n+1); if (trans) { for (j = 0; j < n; j++) { M[i][j].rep.SetMaxLength(2*deg(p)-1); M[i][j] = rep(A[j][i]); } } else { for (j = 0; j < n; j++) { M[i][j].rep.SetMaxLength(2*deg(p)-1); M[i][j] = rep(A[i][j]); } } M[i][n].rep.SetMaxLength(2*deg(p)-1); M[i][n] = rep(b[i]); } zz_pX det; set(det); for (k = 0; k < n; k++) { pos = -1; for (i = k; i < n; i++) { rem(t1, M[i][k], p); M[i][k] = t1; if (pos == -1 && !IsZero(t1)) { pos = i; } } if (pos != -1) { if (k != pos) { swap(M[pos], M[k]); negate(det, det); } MulMod(det, det, M[k][k], p); // make M[k, k] == -1 mod p, and make row k reduced InvMod(t1, M[k][k], p); negate(t1, t1); for (j = k+1; j <= n; j++) { rem(t2, M[k][j], p); MulMod(M[k][j], t2, t1, p); } for (i = k+1; i < n; i++) { // M[i] = M[i] + M[k]*M[i,k] t1 = M[i][k]; // this is already reduced x = M[i].elts() + (k+1); y = M[k].elts() + (k+1); for (j = k+1; j <= n; j++, x++, y++) { // *x = *x + (*y)*t1 mul(t2, *y, t1); add(*x, *x, t2); } } } else { clear(d); return; } } X.SetLength(n); for (i = n-1; i >= 0; i--) { clear(t1); for (j = i+1; j < n; j++) { mul(t2, rep(X[j]), M[i][j]); add(t1, t1, t2); } sub(t1, t1, M[i][n]); conv(X[i], t1); } conv(d, det); }