Added blas for feen

Makefile

@@ -1,5 +1,5 @@
 IRPF90 = irpf90 --codelet=factor_een:100000 #-a -d
-FC     = ifort -xHost -g
+FC     = ifort -xHost -g -mkl=sequential
 FCFLAGS= -O2 -ffree-line-length-none -I .
 NINJA  = ninja
 AR = ar 

README.org

@@ -1,3 +1,36 @@
 * IRPJAST
 
-CHAMP's Jastrow factor computation using the IRPF90 method
+  CHAMP's Jastrow factor computation using the IRPF90 method
+
+  Original equation:
+  
+ $$
+ \sum_{i=2}^{Ne} \sum_{j=1}^i \sum_{pkl} \sum_a^{Nn} c_{apkl}\, r_{ij}^k\, ( R_{ia}^l + R_{ja}^l) ( R_{ia} R_{ja})^m 
+ $$
+
+ Expanding, one obtains:
+ 
+ $$
+ \sum_{i=2}^{Ne} \sum_{j=1}^i \sum_{pkl} \sum_a^{Nn} c_{apkl} R_{ia}^{p-k-l}\, r_{ij}^k\, R_{ja}^{p-k+l} + c_{apkl} R_{ia}^{p-k+l}\, r_{ij}^k\, R_{ja}^{p-k-l}
+ $$
+
+ The equation is symmetric if we exchange $i$ and $j$, so we can rewrite
+
+ $$
+ \sum_{i=1}^{Ne} \sum_{j=1}^{Ne} \sum_{pkl} \sum_a^{Nn} c_{apkl} R_{ia}^{p-k-l}\, r_{ij}^k\, R_{ja}^{p-k+l} 
+ $$
+ 
+ If we reshape $R_{ja}^p$ as a matrix $R_{j,al}$ of size 
+ $N_e \times N_n(N_c+1)$, 
+ for every $k$, we can pre-compute the matrix product
+
+ $$
+ C_{i,al}^{k} = \sum_j r_{ij}^k\, R_{i,al}
+ $$
+
+ and express the total Jastrow as:
+
+ $$
+ \sum_{i=1}^{Ne} \sum_{pkl} \sum_a^{Nn}
+ c_{apkl} R_{ia}^{p-k-l}\, C_{i,a(p-k+l)}^k
+ $$

el_nuc_el.irp.f

@@ -2,10 +2,17 @@ BEGIN_PROVIDER [ double precision, factor_een ]
   implicit none
   BEGIN_DOC
   ! ElectronE-electron-nuclei contribution to Jastrow factor
+  !
+  ! 5436.20340250000
   END_DOC
   integer                        :: i, j, a, p, k, l, lmax, m, n
   double precision               :: cn, accu2, accu
   double precision               :: f(nnuc,0:ncord-2,0:ncord-2)
+  double precision               :: tmp_c(nelec,nnuc,0:ncord,0:ncord-1)
+
+  factor_een = factor_een_blas
+  return
+
 
  factor_een = 0.0d0
 
@@ -18,21 +25,25 @@ BEGIN_PROVIDER [ double precision, factor_een ]
        endif
        do l = 0, lmax
           if ( iand(p - k - l, 1) == 1) cycle
+
           m = (p - k - l) / 2
+
           do a = 1, nnuc
-             cn = cord_vect_lkp(l, k, p, typenuc_arr(a))
              accu2 = 0.d0
+             cn = cord_vect_lkp(l, k, p, typenuc_arr(a))
              do j = 2, nelec
                 accu = 0.d0
-                do i = 1, j - 1
+                do i = 1, j-1
                    accu = accu + rescale_een_e(i,j,k) * &
-                    (rescale_een_n(i,a,l) + rescale_een_n(j,a,l)) * &
-                     rescale_een_n(i,a,m)
+                    rescale_een_n(i,a,m) * rescale_een_n(j,a,m+l) + &
+                    rescale_een_e(i,j,k) * &
+                    rescale_een_n(i,a,m+l) * rescale_een_n(j,a,m)
                 enddo
-                accu2 = accu2 + accu * rescale_een_n(j, a, m) 
+                accu2 = accu2 + accu
              enddo
              factor_een = factor_een + accu2 * cn
           enddo
+
        enddo
     enddo
  enddo
@@ -77,7 +88,7 @@ BEGIN_PROVIDER [ double precision, factor_een_deriv_e, (4, nelec) ]
                 enddo
 
                 do i = 1, nelec
-                   rial = rescale_een_n(i, a, l)
+                   rial = rescale_een_n(i, a, l) + rjal
                    riam = rescale_een_n(i, a, m)
                    rijk = rescale_een_e(i, j, k)
 
@@ -85,24 +96,24 @@ BEGIN_PROVIDER [ double precision, factor_een_deriv_e, (4, nelec) ]
                       drijk(ii) = rescale_een_e_deriv_e(ii, j, i, k)
                    enddo
 
-                   v1 = rijk * (rial + rjal) ! v(x)
+                   v1 = rijk * rial    ! v(x)
                    v2 = rjam_cn * riam ! u(x)
 
                    lap1 = 0.0d0
                    lap2 = 0.0d0
                    do ii = 1, 3
-                      d1 = drijk(ii) * (rial + rjal) + rijk * drjal(ii)
+                      d1 = drijk(ii) * rial + rijk * drjal(ii)
                       d2 = drjam_cn(ii) * riam
                       lap1 = lap1 + d1 * d2
                       lap2 = lap2 + drijk(ii) * drjal(ii)
-                      factor_een_deriv_e(ii, j) += v1 * d2 + d1 * v2
+                      factor_een_deriv_e(ii, j) = factor_een_deriv_e(ii, j) + v1 * d2 + d1 * v2
                    enddo
 
                    ! v(x) u''(x) + 2 * u'(x) v'(x) + u(x) v''(x)
                    ii = 4
-                   d1 = drijk(ii) * (rial + rjal) + rijk * drjal(ii) + 2.0d0 * lap2
+                   d1 = drijk(ii) * rial + rijk * drjal(ii) + lap2 + lap2
                    d2 = drjam_cn(ii) * riam
-                   factor_een_deriv_e(ii, j) += v1 * d2 + d1 * v2 + 2.0d0 * lap1
+                   factor_een_deriv_e(ii, j) = factor_een_deriv_e(ii, j) + v1 * d2 + d1 * v2 + lap1 + lap1
 
                 enddo
              enddo

el_nuc_el_blas.irp.f

@@ -0,0 +1,126 @@
+BEGIN_PROVIDER [ double precision, factor_een_blas ]
+  implicit none
+  BEGIN_DOC
+  ! ElectronE-electron-nuclei contribution to Jastrow factor
+  !
+  ! 4124.84239750000
+  END_DOC
+  integer                        :: i, j, a, p, k, l, lmax, m, n
+  double precision               :: cn(nnuc), accu
+  double precision               :: f(nnuc,0:ncord-2,0:ncord-2)
+  double precision               :: tmp_c(nelec,nnuc,0:ncord,0:ncord-1)
+
+ factor_een_blas = 0.0d0
+
+ ! r_{ij}^k . R_{ja}^l -> tmp_c_{ia}^{kl}
+ do k=0,ncord-1
+   call dgemm('N','N', nelec, nnuc*(ncord+1), nelec, 1.d0,           &
+       rescale_een_e(1,1,k), size(rescale_een_e,1),                  &
+       rescale_een_n(1,1,0), size(rescale_een_n,1), 0.d0,            &
+       tmp_c(1,1,0,k), size(tmp_c,1))
+ enddo
+
+ do p = 2, ncord
+   do k = 0, p - 1
+     m = p-k
+     if (k > 0) then
+       lmax = m
+     else
+       lmax = m - 2
+     endif
+
+     n = shiftr(m,1)
+     do l = iand(m, 1), lmax, 2
+
+       do a = 1, nnuc
+         cn(a) = cord_vect_lkp(l, k, p, typenuc_arr(a))
+       enddo
+
+       do a = 1, nnuc
+         accu = 0.d0
+         do i=1,nelec
+           accu = accu + rescale_een_n(i,a,n) * tmp_c(i,a,n+l,k)
+         enddo
+         factor_een_blas = factor_een_blas + accu * cn(a)
+       enddo
+       n = n-1
+
+     enddo
+   enddo
+ enddo
+
+END_PROVIDER
+
+BEGIN_PROVIDER [ double precision, factor_een_deriv_e_blas, (4, nelec) ]
+ implicit none
+ BEGIN_DOC
+ ! Dimensions 1-3 : dx, dy, dz
+ ! Dimension 4 : d2x + d2y + d2z
+ END_DOC
+ integer :: i, ii, j, a, p, k, l, lmax, m
+ double precision :: riam, rjam_cn, rial, rjal, rijk
+ double precision, dimension(4) :: driam, drjam_cn, drial, drjal, drijk
+ double precision :: cn, v1, v2, d1, d2, lap1, lap2
+
+ factor_een_deriv_e_blas = 0.0d0
+
+ do p = 2, ncord
+    do k = 0 , p - 1
+       if (k /= 0) then
+         lmax = p - k
+       else
+         lmax = p - k - 2
+       endif
+
+       do l = 0, lmax
+          if ( iand(p - k - l, 1) == 1) cycle
+          m = (p - k - l) / 2
+
+          do a = 1, nnuc
+             cn = cord_vect_lkp(l, k, p, typenuc_arr(a))
+
+             do j = 1, nelec
+                rjal = rescale_een_n(j, a, l)
+                rjam_cn = rescale_een_n(j, a, m) * cn
+
+                do ii = 1, 4
+                   drjal(ii) = rescale_een_n_deriv_e(ii, j, a, l)
+                   drjam_cn(ii) = rescale_een_n_deriv_e(ii, j, a, m) * cn
+                enddo
+
+                do i = 1, nelec
+                   rial = rescale_een_n(i, a, l) + rjal
+                   riam = rescale_een_n(i, a, m)
+                   rijk = rescale_een_e(i, j, k)
+
+                   do ii = 1, 4
+                      drijk(ii) = rescale_een_e_deriv_e(ii, j, i, k)
+                   enddo
+
+                   v1 = rijk * rial    ! v(x)
+                   v2 = rjam_cn * riam ! u(x)
+
+                   lap1 = 0.0d0
+                   lap2 = 0.0d0
+                   do ii = 1, 3
+                      d1 = drijk(ii) * rial + rijk * drjal(ii)
+                      d2 = drjam_cn(ii) * riam
+                      lap1 = lap1 + d1 * d2
+                      lap2 = lap2 + drijk(ii) * drjal(ii)
+                      factor_een_deriv_e_blas(ii, j) = factor_een_deriv_e_blas(ii, j) + v1 * d2 + d1 * v2
+                   enddo
+
+                   ! v(x) u''(x) + 2 * u'(x) v'(x) + u(x) v''(x)
+                   ii = 4
+                   d1 = drijk(ii) * rial + rijk * drjal(ii) + lap2 + lap2
+                   d2 = drjam_cn(ii) * riam
+                   factor_een_deriv_e_blas(ii, j) = factor_een_deriv_e_blas(ii, j) + v1 * d2 + d1 * v2 + lap1 + lap1
+
+                enddo
+             enddo
+          enddo
+       enddo
+    enddo
+ enddo
+
+END_PROVIDER