// Copyright ©2016 The Gonum Authors. All rights reserved. // Use of this source code is governed by a BSD-style // license that can be found in the LICENSE file. package gonum import ( "math" "gonum.org/v1/gonum/blas" "gonum.org/v1/gonum/blas/blas64" ) // Dlaqr5 performs a single small-bulge multi-shift QR sweep on an isolated // block of a Hessenberg matrix. // // wantt and wantz determine whether the quasi-triangular Schur factor and the // orthogonal Schur factor, respectively, will be computed. // // kacc22 specifies the computation mode of far-from-diagonal orthogonal // updates. Permitted values are: // 0: Dlaqr5 will not accumulate reflections and will not use matrix-matrix // multiply to update far-from-diagonal matrix entries. // 1: Dlaqr5 will accumulate reflections and use matrix-matrix multiply to // update far-from-diagonal matrix entries. // 2: Dlaqr5 will accumulate reflections, use matrix-matrix multiply to update // far-from-diagonal matrix entries, and take advantage of 2×2 block // structure during matrix multiplies. // For other values of kacc2 Dlaqr5 will panic. // // n is the order of the Hessenberg matrix H. // // ktop and kbot are indices of the first and last row and column of an isolated // diagonal block upon which the QR sweep will be applied. It must hold that // ktop == 0, or 0 < ktop <= n-1 and H[ktop, ktop-1] == 0, and // kbot == n-1, or 0 <= kbot < n-1 and H[kbot+1, kbot] == 0, // otherwise Dlaqr5 will panic. // // nshfts is the number of simultaneous shifts. It must be positive and even, // otherwise Dlaqr5 will panic. // // sr and si contain the real and imaginary parts, respectively, of the shifts // of origin that define the multi-shift QR sweep. On return both slices may be // reordered by Dlaqr5. Their length must be equal to nshfts, otherwise Dlaqr5 // will panic. // // h and ldh represent the Hessenberg matrix H of size n×n. On return // multi-shift QR sweep with shifts sr+i*si has been applied to the isolated // diagonal block in rows and columns ktop through kbot, inclusive. // // iloz and ihiz specify the rows of Z to which transformations will be applied // if wantz is true. It must hold that 0 <= iloz <= ihiz < n, otherwise Dlaqr5 // will panic. // // z and ldz represent the matrix Z of size n×n. If wantz is true, the QR sweep // orthogonal similarity transformation is accumulated into // z[iloz:ihiz,iloz:ihiz] from the right, otherwise z not referenced. // // v and ldv represent an auxiliary matrix V of size (nshfts/2)×3. Note that V // is transposed with respect to the reference netlib implementation. // // u and ldu represent an auxiliary matrix of size (3*nshfts-3)×(3*nshfts-3). // // wh and ldwh represent an auxiliary matrix of size (3*nshfts-3)×nh. // // wv and ldwv represent an auxiliary matrix of size nv×(3*nshfts-3). // // Dlaqr5 is an internal routine. It is exported for testing purposes. func (impl Implementation) Dlaqr5(wantt, wantz bool, kacc22 int, n, ktop, kbot, nshfts int, sr, si []float64, h []float64, ldh int, iloz, ihiz int, z []float64, ldz int, v []float64, ldv int, u []float64, ldu int, nv int, wv []float64, ldwv int, nh int, wh []float64, ldwh int) { checkMatrix(n, n, h, ldh) if ktop < 0 || n <= ktop { panic("lapack: invalid value of ktop") } if ktop > 0 && h[ktop*ldh+ktop-1] != 0 { panic("lapack: diagonal block is not isolated") } if kbot < 0 || n <= kbot { panic("lapack: invalid value of kbot") } if kbot < n-1 && h[(kbot+1)*ldh+kbot] != 0 { panic("lapack: diagonal block is not isolated") } if nshfts < 0 || nshfts&0x1 != 0 { panic("lapack: invalid number of shifts") } if len(sr) != nshfts || len(si) != nshfts { panic(badSlice) // TODO(vladimir-ch) Another message? } if wantz { if ihiz >= n { panic("lapack: invalid value of ihiz") } if iloz < 0 || ihiz < iloz { panic("lapack: invalid value of iloz") } checkMatrix(n, n, z, ldz) } checkMatrix(nshfts/2, 3, v, ldv) // Transposed w.r.t. lapack. checkMatrix(3*nshfts-3, 3*nshfts-3, u, ldu) checkMatrix(nv, 3*nshfts-3, wv, ldwv) checkMatrix(3*nshfts-3, nh, wh, ldwh) if kacc22 != 0 && kacc22 != 1 && kacc22 != 2 { panic("lapack: invalid value of kacc22") } // If there are no shifts, then there is nothing to do. if nshfts < 2 { return } // If the active block is empty or 1×1, then there is nothing to do. if ktop >= kbot { return } // Shuffle shifts into pairs of real shifts and pairs of complex // conjugate shifts assuming complex conjugate shifts are already // adjacent to one another. for i := 0; i < nshfts-2; i += 2 { if si[i] == -si[i+1] { continue } sr[i], sr[i+1], sr[i+2] = sr[i+1], sr[i+2], sr[i] si[i], si[i+1], si[i+2] = si[i+1], si[i+2], si[i] } // Note: lapack says that nshfts must be even but allows it to be odd // anyway. We panic above if nshfts is not even, so reducing it by one // is unnecessary. The only caller Dlaqr04 uses only even nshfts. // // The original comment and code from lapack-3.6.0/SRC/dlaqr5.f:341: // * ==== NSHFTS is supposed to be even, but if it is odd, // * . then simply reduce it by one. The shuffle above // * . ensures that the dropped shift is real and that // * . the remaining shifts are paired. ==== // * // NS = NSHFTS - MOD( NSHFTS, 2 ) ns := nshfts safmin := dlamchS ulp := dlamchP smlnum := safmin * float64(n) / ulp // Use accumulated reflections to update far-from-diagonal entries? accum := kacc22 == 1 || kacc22 == 2 // If so, exploit the 2×2 block structure? blk22 := ns > 2 && kacc22 == 2 // Clear trash. if ktop+2 <= kbot { h[(ktop+2)*ldh+ktop] = 0 } // nbmps = number of 2-shift bulges in the chain. nbmps := ns / 2 // kdu = width of slab. kdu := 6*nbmps - 3 // Create and chase chains of nbmps bulges. for incol := 3*(1-nbmps) + ktop - 1; incol <= kbot-2; incol += 3*nbmps - 2 { ndcol := incol + kdu if accum { impl.Dlaset(blas.All, kdu, kdu, 0, 1, u, ldu) } // Near-the-diagonal bulge chase. The following loop performs // the near-the-diagonal part of a small bulge multi-shift QR // sweep. Each 6*nbmps-2 column diagonal chunk extends from // column incol to column ndcol (including both column incol and // column ndcol). The following loop chases a 3*nbmps column // long chain of nbmps bulges 3*nbmps-2 columns to the right. // (incol may be less than ktop and ndcol may be greater than // kbot indicating phantom columns from which to chase bulges // before they are actually introduced or to which to chase // bulges beyond column kbot.) for krcol := incol; krcol <= min(incol+3*nbmps-3, kbot-2); krcol++ { // Bulges number mtop to mbot are active double implicit // shift bulges. There may or may not also be small 2×2 // bulge, if there is room. The inactive bulges (if any) // must wait until the active bulges have moved down the // diagonal to make room. The phantom matrix paradigm // described above helps keep track. mtop := max(0, ((ktop-1)-krcol+2)/3) mbot := min(nbmps, (kbot-krcol)/3) - 1 m22 := mbot + 1 bmp22 := (mbot < nbmps-1) && (krcol+3*m22 == kbot-2) // Generate reflections to chase the chain right one // column. (The minimum value of k is ktop-1.) for m := mtop; m <= mbot; m++ { k := krcol + 3*m if k == ktop-1 { impl.Dlaqr1(3, h[ktop*ldh+ktop:], ldh, sr[2*m], si[2*m], sr[2*m+1], si[2*m+1], v[m*ldv:m*ldv+3]) alpha := v[m*ldv] _, v[m*ldv] = impl.Dlarfg(3, alpha, v[m*ldv+1:m*ldv+3], 1) continue } beta := h[(k+1)*ldh+k] v[m*ldv+1] = h[(k+2)*ldh+k] v[m*ldv+2] = h[(k+3)*ldh+k] beta, v[m*ldv] = impl.Dlarfg(3, beta, v[m*ldv+1:m*ldv+3], 1) // A bulge may collapse because of vigilant deflation or // destructive underflow. In the underflow case, try the // two-small-subdiagonals trick to try to reinflate the // bulge. if h[(k+3)*ldh+k] != 0 || h[(k+3)*ldh+k+1] != 0 || h[(k+3)*ldh+k+2] == 0 { // Typical case: not collapsed (yet). h[(k+1)*ldh+k] = beta h[(k+2)*ldh+k] = 0 h[(k+3)*ldh+k] = 0 continue } // Atypical case: collapsed. Attempt to reintroduce // ignoring H[k+1,k] and H[k+2,k]. If the fill // resulting from the new reflector is too large, // then abandon it. Otherwise, use the new one. var vt [3]float64 impl.Dlaqr1(3, h[(k+1)*ldh+k+1:], ldh, sr[2*m], si[2*m], sr[2*m+1], si[2*m+1], vt[:]) alpha := vt[0] _, vt[0] = impl.Dlarfg(3, alpha, vt[1:3], 1) refsum := vt[0] * (h[(k+1)*ldh+k] + vt[1]*h[(k+2)*ldh+k]) dsum := math.Abs(h[k*ldh+k]) + math.Abs(h[(k+1)*ldh+k+1]) + math.Abs(h[(k+2)*ldh+k+2]) if math.Abs(h[(k+2)*ldh+k]-refsum*vt[1])+math.Abs(refsum*vt[2]) > ulp*dsum { // Starting a new bulge here would create // non-negligible fill. Use the old one with // trepidation. h[(k+1)*ldh+k] = beta h[(k+2)*ldh+k] = 0 h[(k+3)*ldh+k] = 0 continue } else { // Starting a new bulge here would create // only negligible fill. Replace the old // reflector with the new one. h[(k+1)*ldh+k] -= refsum h[(k+2)*ldh+k] = 0 h[(k+3)*ldh+k] = 0 v[m*ldv] = vt[0] v[m*ldv+1] = vt[1] v[m*ldv+2] = vt[2] } } // Generate a 2×2 reflection, if needed. if bmp22 { k := krcol + 3*m22 if k == ktop-1 { impl.Dlaqr1(2, h[(k+1)*ldh+k+1:], ldh, sr[2*m22], si[2*m22], sr[2*m22+1], si[2*m22+1], v[m22*ldv:m22*ldv+2]) beta := v[m22*ldv] _, v[m22*ldv] = impl.Dlarfg(2, beta, v[m22*ldv+1:m22*ldv+2], 1) } else { beta := h[(k+1)*ldh+k] v[m22*ldv+1] = h[(k+2)*ldh+k] beta, v[m22*ldv] = impl.Dlarfg(2, beta, v[m22*ldv+1:m22*ldv+2], 1) h[(k+1)*ldh+k] = beta h[(k+2)*ldh+k] = 0 } } // Multiply H by reflections from the left. var jbot int switch { case accum: jbot = min(ndcol, kbot) case wantt: jbot = n - 1 default: jbot = kbot } for j := max(ktop, krcol); j <= jbot; j++ { mend := min(mbot+1, (j-krcol+2)/3) - 1 for m := mtop; m <= mend; m++ { k := krcol + 3*m refsum := v[m*ldv] * (h[(k+1)*ldh+j] + v[m*ldv+1]*h[(k+2)*ldh+j] + v[m*ldv+2]*h[(k+3)*ldh+j]) h[(k+1)*ldh+j] -= refsum h[(k+2)*ldh+j] -= refsum * v[m*ldv+1] h[(k+3)*ldh+j] -= refsum * v[m*ldv+2] } } if bmp22 { k := krcol + 3*m22 for j := max(k+1, ktop); j <= jbot; j++ { refsum := v[m22*ldv] * (h[(k+1)*ldh+j] + v[m22*ldv+1]*h[(k+2)*ldh+j]) h[(k+1)*ldh+j] -= refsum h[(k+2)*ldh+j] -= refsum * v[m22*ldv+1] } } // Multiply H by reflections from the right. Delay filling in the last row // until the vigilant deflation check is complete. var jtop int switch { case accum: jtop = max(ktop, incol) case wantt: jtop = 0 default: jtop = ktop } for m := mtop; m <= mbot; m++ { if v[m*ldv] == 0 { continue } k := krcol + 3*m for j := jtop; j <= min(kbot, k+3); j++ { refsum := v[m*ldv] * (h[j*ldh+k+1] + v[m*ldv+1]*h[j*ldh+k+2] + v[m*ldv+2]*h[j*ldh+k+3]) h[j*ldh+k+1] -= refsum h[j*ldh+k+2] -= refsum * v[m*ldv+1] h[j*ldh+k+3] -= refsum * v[m*ldv+2] } if accum { // Accumulate U. (If necessary, update Z later with with an // efficient matrix-matrix multiply.) kms := k - incol for j := max(0, ktop-incol-1); j < kdu; j++ { refsum := v[m*ldv] * (u[j*ldu+kms] + v[m*ldv+1]*u[j*ldu+kms+1] + v[m*ldv+2]*u[j*ldu+kms+2]) u[j*ldu+kms] -= refsum u[j*ldu+kms+1] -= refsum * v[m*ldv+1] u[j*ldu+kms+2] -= refsum * v[m*ldv+2] } } else if wantz { // U is not accumulated, so update Z now by multiplying by // reflections from the right. for j := iloz; j <= ihiz; j++ { refsum := v[m*ldv] * (z[j*ldz+k+1] + v[m*ldv+1]*z[j*ldz+k+2] + v[m*ldv+2]*z[j*ldz+k+3]) z[j*ldz+k+1] -= refsum z[j*ldz+k+2] -= refsum * v[m*ldv+1] z[j*ldz+k+3] -= refsum * v[m*ldv+2] } } } // Special case: 2×2 reflection (if needed). if bmp22 && v[m22*ldv] != 0 { k := krcol + 3*m22 for j := jtop; j <= min(kbot, k+3); j++ { refsum := v[m22*ldv] * (h[j*ldh+k+1] + v[m22*ldv+1]*h[j*ldh+k+2]) h[j*ldh+k+1] -= refsum h[j*ldh+k+2] -= refsum * v[m22*ldv+1] } if accum { kms := k - incol for j := max(0, ktop-incol-1); j < kdu; j++ { refsum := v[m22*ldv] * (u[j*ldu+kms] + v[m22*ldv+1]*u[j*ldu+kms+1]) u[j*ldu+kms] -= refsum u[j*ldu+kms+1] -= refsum * v[m22*ldv+1] } } else if wantz { for j := iloz; j <= ihiz; j++ { refsum := v[m22*ldv] * (z[j*ldz+k+1] + v[m22*ldv+1]*z[j*ldz+k+2]) z[j*ldz+k+1] -= refsum z[j*ldz+k+2] -= refsum * v[m22*ldv+1] } } } // Vigilant deflation check. mstart := mtop if krcol+3*mstart < ktop { mstart++ } mend := mbot if bmp22 { mend++ } if krcol == kbot-2 { mend++ } for m := mstart; m <= mend; m++ { k := min(kbot-1, krcol+3*m) // The following convergence test requires that the tradition // small-compared-to-nearby-diagonals criterion and the Ahues & // Tisseur (LAWN 122, 1997) criteria both be satisfied. The latter // improves accuracy in some examples. Falling back on an alternate // convergence criterion when tst1 or tst2 is zero (as done here) is // traditional but probably unnecessary. if h[(k+1)*ldh+k] == 0 { continue } tst1 := math.Abs(h[k*ldh+k]) + math.Abs(h[(k+1)*ldh+k+1]) if tst1 == 0 { if k >= ktop+1 { tst1 += math.Abs(h[k*ldh+k-1]) } if k >= ktop+2 { tst1 += math.Abs(h[k*ldh+k-2]) } if k >= ktop+3 { tst1 += math.Abs(h[k*ldh+k-3]) } if k <= kbot-2 { tst1 += math.Abs(h[(k+2)*ldh+k+1]) } if k <= kbot-3 { tst1 += math.Abs(h[(k+3)*ldh+k+1]) } if k <= kbot-4 { tst1 += math.Abs(h[(k+4)*ldh+k+1]) } } if math.Abs(h[(k+1)*ldh+k]) <= math.Max(smlnum, ulp*tst1) { h12 := math.Max(math.Abs(h[(k+1)*ldh+k]), math.Abs(h[k*ldh+k+1])) h21 := math.Min(math.Abs(h[(k+1)*ldh+k]), math.Abs(h[k*ldh+k+1])) h11 := math.Max(math.Abs(h[(k+1)*ldh+k+1]), math.Abs(h[k*ldh+k]-h[(k+1)*ldh+k+1])) h22 := math.Min(math.Abs(h[(k+1)*ldh+k+1]), math.Abs(h[k*ldh+k]-h[(k+1)*ldh+k+1])) scl := h11 + h12 tst2 := h22 * (h11 / scl) if tst2 == 0 || h21*(h12/scl) <= math.Max(smlnum, ulp*tst2) { h[(k+1)*ldh+k] = 0 } } } // Fill in the last row of each bulge. mend = min(nbmps, (kbot-krcol-1)/3) - 1 for m := mtop; m <= mend; m++ { k := krcol + 3*m refsum := v[m*ldv] * v[m*ldv+2] * h[(k+4)*ldh+k+3] h[(k+4)*ldh+k+1] = -refsum h[(k+4)*ldh+k+2] = -refsum * v[m*ldv+1] h[(k+4)*ldh+k+3] -= refsum * v[m*ldv+2] } } // Use U (if accumulated) to update far-from-diagonal entries in H. // If required, use U to update Z as well. if !accum { continue } var jtop, jbot int if wantt { jtop = 0 jbot = n - 1 } else { jtop = ktop jbot = kbot } bi := blas64.Implementation() if !blk22 || incol < ktop || kbot < ndcol || ns <= 2 { // Updates not exploiting the 2×2 block structure of U. k0 and nu keep track // of the location and size of U in the special cases of introducing bulges // and chasing bulges off the bottom. In these special cases and in case the // number of shifts is ns = 2, there is no 2×2 block structure to exploit. k0 := max(0, ktop-incol-1) nu := kdu - max(0, ndcol-kbot) - k0 // Horizontal multiply. for jcol := min(ndcol, kbot) + 1; jcol <= jbot; jcol += nh { jlen := min(nh, jbot-jcol+1) bi.Dgemm(blas.Trans, blas.NoTrans, nu, jlen, nu, 1, u[k0*ldu+k0:], ldu, h[(incol+k0+1)*ldh+jcol:], ldh, 0, wh, ldwh) impl.Dlacpy(blas.All, nu, jlen, wh, ldwh, h[(incol+k0+1)*ldh+jcol:], ldh) } // Vertical multiply. for jrow := jtop; jrow <= max(ktop, incol)-1; jrow += nv { jlen := min(nv, max(ktop, incol)-jrow) bi.Dgemm(blas.NoTrans, blas.NoTrans, jlen, nu, nu, 1, h[jrow*ldh+incol+k0+1:], ldh, u[k0*ldu+k0:], ldu, 0, wv, ldwv) impl.Dlacpy(blas.All, jlen, nu, wv, ldwv, h[jrow*ldh+incol+k0+1:], ldh) } // Z multiply (also vertical). if wantz { for jrow := iloz; jrow <= ihiz; jrow += nv { jlen := min(nv, ihiz-jrow+1) bi.Dgemm(blas.NoTrans, blas.NoTrans, jlen, nu, nu, 1, z[jrow*ldz+incol+k0+1:], ldz, u[k0*ldu+k0:], ldu, 0, wv, ldwv) impl.Dlacpy(blas.All, jlen, nu, wv, ldwv, z[jrow*ldz+incol+k0+1:], ldz) } } continue } // Updates exploiting U's 2×2 block structure. // i2, i4, j2, j4 are the last rows and columns of the blocks. i2 := (kdu + 1) / 2 i4 := kdu j2 := i4 - i2 j4 := kdu // kzs and knz deal with the band of zeros along the diagonal of one of the // triangular blocks. kzs := (j4 - j2) - (ns + 1) knz := ns + 1 // Horizontal multiply. for jcol := min(ndcol, kbot) + 1; jcol <= jbot; jcol += nh { jlen := min(nh, jbot-jcol+1) // Copy bottom of H to top+kzs of scratch (the first kzs // rows get multiplied by zero). impl.Dlacpy(blas.All, knz, jlen, h[(incol+1+j2)*ldh+jcol:], ldh, wh[kzs*ldwh:], ldwh) // Multiply by U21^T. impl.Dlaset(blas.All, kzs, jlen, 0, 0, wh, ldwh) bi.Dtrmm(blas.Left, blas.Upper, blas.Trans, blas.NonUnit, knz, jlen, 1, u[j2*ldu+kzs:], ldu, wh[kzs*ldwh:], ldwh) // Multiply top of H by U11^T. bi.Dgemm(blas.Trans, blas.NoTrans, i2, jlen, j2, 1, u, ldu, h[(incol+1)*ldh+jcol:], ldh, 1, wh, ldwh) // Copy top of H to bottom of WH. impl.Dlacpy(blas.All, j2, jlen, h[(incol+1)*ldh+jcol:], ldh, wh[i2*ldwh:], ldwh) // Multiply by U21^T. bi.Dtrmm(blas.Left, blas.Lower, blas.Trans, blas.NonUnit, j2, jlen, 1, u[i2:], ldu, wh[i2*ldwh:], ldwh) // Multiply by U22. bi.Dgemm(blas.Trans, blas.NoTrans, i4-i2, jlen, j4-j2, 1, u[j2*ldu+i2:], ldu, h[(incol+1+j2)*ldh+jcol:], ldh, 1, wh[i2*ldwh:], ldwh) // Copy it back. impl.Dlacpy(blas.All, kdu, jlen, wh, ldwh, h[(incol+1)*ldh+jcol:], ldh) } // Vertical multiply. for jrow := jtop; jrow <= max(incol, ktop)-1; jrow += nv { jlen := min(nv, max(incol, ktop)-jrow) // Copy right of H to scratch (the first kzs columns get multiplied // by zero). impl.Dlacpy(blas.All, jlen, knz, h[jrow*ldh+incol+1+j2:], ldh, wv[kzs:], ldwv) // Multiply by U21. impl.Dlaset(blas.All, jlen, kzs, 0, 0, wv, ldwv) bi.Dtrmm(blas.Right, blas.Upper, blas.NoTrans, blas.NonUnit, jlen, knz, 1, u[j2*ldu+kzs:], ldu, wv[kzs:], ldwv) // Multiply by U11. bi.Dgemm(blas.NoTrans, blas.NoTrans, jlen, i2, j2, 1, h[jrow*ldh+incol+1:], ldh, u, ldu, 1, wv, ldwv) // Copy left of H to right of scratch. impl.Dlacpy(blas.All, jlen, j2, h[jrow*ldh+incol+1:], ldh, wv[i2:], ldwv) // Multiply by U21. bi.Dtrmm(blas.Right, blas.Lower, blas.NoTrans, blas.NonUnit, jlen, i4-i2, 1, u[i2:], ldu, wv[i2:], ldwv) // Multiply by U22. bi.Dgemm(blas.NoTrans, blas.NoTrans, jlen, i4-i2, j4-j2, 1, h[jrow*ldh+incol+1+j2:], ldh, u[j2*ldu+i2:], ldu, 1, wv[i2:], ldwv) // Copy it back. impl.Dlacpy(blas.All, jlen, kdu, wv, ldwv, h[jrow*ldh+incol+1:], ldh) } if !wantz { continue } // Multiply Z (also vertical). for jrow := iloz; jrow <= ihiz; jrow += nv { jlen := min(nv, ihiz-jrow+1) // Copy right of Z to left of scratch (first kzs columns get // multiplied by zero). impl.Dlacpy(blas.All, jlen, knz, z[jrow*ldz+incol+1+j2:], ldz, wv[kzs:], ldwv) // Multiply by U12. impl.Dlaset(blas.All, jlen, kzs, 0, 0, wv, ldwv) bi.Dtrmm(blas.Right, blas.Upper, blas.NoTrans, blas.NonUnit, jlen, knz, 1, u[j2*ldu+kzs:], ldu, wv[kzs:], ldwv) // Multiply by U11. bi.Dgemm(blas.NoTrans, blas.NoTrans, jlen, i2, j2, 1, z[jrow*ldz+incol+1:], ldz, u, ldu, 1, wv, ldwv) // Copy left of Z to right of scratch. impl.Dlacpy(blas.All, jlen, j2, z[jrow*ldz+incol+1:], ldz, wv[i2:], ldwv) // Multiply by U21. bi.Dtrmm(blas.Right, blas.Lower, blas.NoTrans, blas.NonUnit, jlen, i4-i2, 1, u[i2:], ldu, wv[i2:], ldwv) // Multiply by U22. bi.Dgemm(blas.NoTrans, blas.NoTrans, jlen, i4-i2, j4-j2, 1, z[jrow*ldz+incol+1+j2:], ldz, u[j2*ldu+i2:], ldu, 1, wv[i2:], ldwv) // Copy the result back to Z. impl.Dlacpy(blas.All, jlen, kdu, wv, ldwv, z[jrow*ldz+incol+1:], ldz) } } }