!!$ !!$ Parallel Sparse BLAS version 3.0 !!$ (C) Copyright 2006, 2007, 2008, 2009, 2010, 2012 !!$ Salvatore Filippone University of Rome Tor Vergata !!$ Alfredo Buttari CNRS-IRIT, Toulouse !!$ !!$ Redistribution and use in source and binary forms, with or without !!$ modification, are permitted provided that the following conditions !!$ are met: !!$ 1. Redistributions of source code must retain the above copyright !!$ notice, this list of conditions and the following disclaimer. !!$ 2. Redistributions in binary form must reproduce the above copyright !!$ notice, this list of conditions, and the following disclaimer in the !!$ documentation and/or other materials provided with the distribution. !!$ 3. The name of the PSBLAS group or the names of its contributors may !!$ not be used to endorse or promote products derived from this !!$ software without specific written permission. !!$ !!$ THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS !!$ ``AS IS'' AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED !!$ TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR !!$ PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE PSBLAS GROUP OR ITS CONTRIBUTORS !!$ BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR !!$ CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF !!$ SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS !!$ INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN !!$ CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) !!$ ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE !!$ POSSIBILITY OF SUCH DAMAGE. !!$ !!$ ! ! package: psb_z_base_vect_mod ! ! This module contains the definition of the psb_z_base_vect type which ! is a container for dense vectors. ! This is encapsulated instead of being just a simple array to allow for ! more complicated situations, such as GPU programming, where the memory ! area we are interested in is not easily accessible from the host/Fortran ! side. It is also meant to be encapsulated in an outer type, to allow ! runtime switching as per the STATE design pattern, similar to the ! sparse matrix types. ! ! module psb_z_base_vect_mod use psb_const_mod use psb_error_mod !> \namespace psb_base_mod \class psb_z_base_vect_type !! The psb_z_base_vect_type !! defines a middle level complex(psb_dpk_) encapsulated dense vector. !! The encapsulation is needed, in place of a simple array, to allow !! for complicated situations, such as GPU programming, where the memory !! area we are interested in is not easily accessible from the host/Fortran !! side. It is also meant to be encapsulated in an outer type, to allow !! runtime switching as per the STATE design pattern, similar to the !! sparse matrix types. !! type psb_z_base_vect_type complex(psb_dpk_), allocatable :: v(:) contains ! ! Constructors/allocators ! procedure, pass(x) :: bld_x => z_base_bld_x procedure, pass(x) :: bld_n => z_base_bld_n generic, public :: bld => bld_x, bld_n procedure, pass(x) :: all => z_base_all ! ! Insert/set. Assembly and free. ! Assembly does almost nothing here, but is important ! in derived classes. ! procedure, pass(x) :: ins => z_base_ins procedure, pass(x) :: zero => z_base_zero procedure, pass(x) :: asb => z_base_asb procedure, pass(x) :: free => z_base_free ! ! Sync: centerpiece of handling of external storage. ! Any derived class having extra storage upon sync ! will guarantee that both fortran/host side and ! external side contain the same data. The base ! version is only a placeholder. ! procedure, pass(x) :: sync => z_base_sync procedure, pass(x) :: is_host => z_base_is_host procedure, pass(x) :: is_dev => z_base_is_dev procedure, pass(x) :: is_sync => z_base_is_sync procedure, pass(x) :: set_host => z_base_set_host procedure, pass(x) :: set_dev => z_base_set_dev procedure, pass(x) :: set_sync => z_base_set_sync ! ! Basic info procedure, pass(x) :: get_nrows => z_base_get_nrows procedure, pass(x) :: sizeof => z_base_sizeof ! ! Set/get data from/to an external array; also ! overload assignment. ! procedure, pass(x) :: get_vect => z_base_get_vect procedure, pass(x) :: set_scal => z_base_set_scal procedure, pass(x) :: set_vect => z_base_set_vect generic, public :: set => set_vect, set_scal ! ! Dot product and AXPBY ! procedure, pass(x) :: dot_v => z_base_dot_v procedure, pass(x) :: dot_a => z_base_dot_a generic, public :: dot => dot_v, dot_a procedure, pass(y) :: axpby_v => z_base_axpby_v procedure, pass(y) :: axpby_a => z_base_axpby_a generic, public :: axpby => axpby_v, axpby_a ! ! Vector by vector multiplication. Need all variants ! to handle multiple requirements from preconditioners ! procedure, pass(y) :: mlt_v => z_base_mlt_v procedure, pass(y) :: mlt_a => z_base_mlt_a procedure, pass(z) :: mlt_a_2 => z_base_mlt_a_2 procedure, pass(z) :: mlt_v_2 => z_base_mlt_v_2 procedure, pass(z) :: mlt_va => z_base_mlt_va procedure, pass(z) :: mlt_av => z_base_mlt_av generic, public :: mlt => mlt_v, mlt_a, mlt_a_2, mlt_v_2, mlt_av, mlt_va ! ! Scaling and norms ! procedure, pass(x) :: scal => z_base_scal procedure, pass(x) :: nrm2 => z_base_nrm2 procedure, pass(x) :: amax => z_base_amax procedure, pass(x) :: asum => z_base_asum ! ! Gather/scatter. These are needed for MPI interfacing. ! May have to be reworked. ! procedure, pass(x) :: gthab => z_base_gthab procedure, pass(x) :: gthzv => z_base_gthzv generic, public :: gth => gthab, gthzv procedure, pass(y) :: sctb => z_base_sctb generic, public :: sct => sctb end type psb_z_base_vect_type public :: psb_z_base_vect private :: constructor, size_const interface psb_z_base_vect module procedure constructor, size_const end interface psb_z_base_vect contains ! ! Constructors. ! function constructor(x) result(this) complex(psb_dpk_) :: x(:) type(psb_z_base_vect_type) :: this integer(psb_ipk_) :: info this%v = x call this%asb(size(x,kind=psb_ipk_),info) end function constructor function size_const(n) result(this) integer(psb_ipk_), intent(in) :: n type(psb_z_base_vect_type) :: this integer(psb_ipk_) :: info call this%asb(n,info) end function size_const ! ! Build from a sample ! subroutine z_base_bld_x(x,this) use psb_realloc_mod complex(psb_dpk_), intent(in) :: this(:) class(psb_z_base_vect_type), intent(inout) :: x integer(psb_ipk_) :: info call psb_realloc(size(this),x%v,info) if (info /= 0) then call psb_errpush(psb_err_alloc_dealloc_,'base_vect_bld') return end if x%v(:) = this(:) end subroutine z_base_bld_x ! ! Create with size, but no initialization ! subroutine z_base_bld_n(x,n) use psb_realloc_mod integer(psb_ipk_), intent(in) :: n class(psb_z_base_vect_type), intent(inout) :: x integer(psb_ipk_) :: info call psb_realloc(n,x%v,info) call x%asb(n,info) end subroutine z_base_bld_n subroutine z_base_all(n, x, info) use psi_serial_mod use psb_realloc_mod implicit none integer(psb_ipk_), intent(in) :: n class(psb_z_base_vect_type), intent(out) :: x integer(psb_ipk_), intent(out) :: info call psb_realloc(n,x%v,info) end subroutine z_base_all ! ! Insert a bunch of values at specified positions. ! subroutine z_base_ins(n,irl,val,dupl,x,info) use psi_serial_mod implicit none class(psb_z_base_vect_type), intent(inout) :: x integer(psb_ipk_), intent(in) :: n, dupl integer(psb_ipk_), intent(in) :: irl(:) complex(psb_dpk_), intent(in) :: val(:) integer(psb_ipk_), intent(out) :: info integer(psb_ipk_) :: i info = 0 if (psb_errstatus_fatal()) return if (.not.allocated(x%v)) then info = psb_err_invalid_vect_state_ else if (n > min(size(irl),size(val))) then info = psb_err_invalid_input_ else select case(dupl) case(psb_dupl_ovwrt_) do i = 1, n !loop over all val's rows ! row actual block row if (irl(i) > 0) then ! this row belongs to me ! copy i-th row of block val in x x%v(irl(i)) = val(i) end if enddo case(psb_dupl_add_) do i = 1, n !loop over all val's rows if (irl(i) > 0) then ! this row belongs to me ! copy i-th row of block val in x x%v(irl(i)) = x%v(irl(i)) + val(i) end if enddo case default info = 321 !!$ call psb_errpush(info,name) !!$ goto 9999 end select end if if (info /= 0) then call psb_errpush(info,'base_vect_ins') return end if end subroutine z_base_ins ! subroutine z_base_zero(x) use psi_serial_mod implicit none class(psb_z_base_vect_type), intent(inout) :: x if (allocated(x%v)) x%v=zzero end subroutine z_base_zero ! ! Assembly. ! For derived classes: after this the vector ! storage is supposed to be in sync. ! subroutine z_base_asb(n, x, info) use psi_serial_mod use psb_realloc_mod implicit none integer(psb_ipk_), intent(in) :: n class(psb_z_base_vect_type), intent(inout) :: x integer(psb_ipk_), intent(out) :: info if (x%get_nrows() < n) & & call psb_realloc(n,x%v,info) if (info /= 0) & & call psb_errpush(psb_err_alloc_dealloc_,'vect_asb') end subroutine z_base_asb subroutine z_base_free(x, info) use psi_serial_mod use psb_realloc_mod implicit none class(psb_z_base_vect_type), intent(inout) :: x integer(psb_ipk_), intent(out) :: info info = 0 if (allocated(x%v)) deallocate(x%v, stat=info) if (info /= 0) call & & psb_errpush(psb_err_alloc_dealloc_,'vect_free') end subroutine z_base_free ! ! The base version of SYNC & friends does nothing, it's just ! a placeholder. ! subroutine z_base_sync(x) implicit none class(psb_z_base_vect_type), intent(inout) :: x end subroutine z_base_sync subroutine z_base_set_host(x) implicit none class(psb_z_base_vect_type), intent(inout) :: x end subroutine z_base_set_host subroutine z_base_set_dev(x) implicit none class(psb_z_base_vect_type), intent(inout) :: x end subroutine z_base_set_dev subroutine z_base_set_sync(x) implicit none class(psb_z_base_vect_type), intent(inout) :: x end subroutine z_base_set_sync function z_base_is_dev(x) result(res) implicit none class(psb_z_base_vect_type), intent(in) :: x logical :: res res = .false. end function z_base_is_dev function z_base_is_host(x) result(res) implicit none class(psb_z_base_vect_type), intent(in) :: x logical :: res res = .true. end function z_base_is_host function z_base_is_sync(x) result(res) implicit none class(psb_z_base_vect_type), intent(in) :: x logical :: res res = .true. end function z_base_is_sync ! ! Size info. ! function z_base_get_nrows(x) result(res) implicit none class(psb_z_base_vect_type), intent(in) :: x integer(psb_ipk_) :: res res = 0 if (allocated(x%v)) res = size(x%v) end function z_base_get_nrows function z_base_sizeof(x) result(res) implicit none class(psb_z_base_vect_type), intent(in) :: x integer(psb_long_int_k_) :: res ! Force 8-byte integers. res = (1_psb_long_int_k_ * (2*psb_sizeof_dp)) * x%get_nrows() end function z_base_sizeof ! ! Two versions of extracting an array: one of them ! overload the assignment. ! function z_base_get_vect(x) result(res) class(psb_z_base_vect_type), intent(inout) :: x complex(psb_dpk_), allocatable :: res(:) integer(psb_ipk_) :: info if (.not.allocated(x%v)) return call x%sync() allocate(res(x%get_nrows()),stat=info) if (info /= 0) then call psb_errpush(psb_err_alloc_dealloc_,'base_get_vect') return end if res(:) = x%v(:) end function z_base_get_vect ! ! Reset all values ! subroutine z_base_set_scal(x,val) class(psb_z_base_vect_type), intent(inout) :: x complex(psb_dpk_), intent(in) :: val integer(psb_ipk_) :: info x%v = val end subroutine z_base_set_scal subroutine z_base_set_vect(x,val) class(psb_z_base_vect_type), intent(inout) :: x complex(psb_dpk_), intent(in) :: val(:) integer(psb_ipk_) :: nr integer(psb_ipk_) :: info if (allocated(x%v)) then nr = min(size(x%v),size(val)) x%v(1:nr) = val(1:nr) else x%v = val end if end subroutine z_base_set_vect ! ! Dot products ! function z_base_dot_v(n,x,y) result(res) implicit none class(psb_z_base_vect_type), intent(inout) :: x, y integer(psb_ipk_), intent(in) :: n complex(psb_dpk_) :: res complex(psb_dpk_), external :: zdotc res = zzero ! ! Note: this is the base implementation. ! When we get here, we are sure that X is of ! TYPE psb_z_base_vect. ! If Y is not, throw the burden on it, implicitly ! calling dot_a ! select type(yy => y) type is (psb_z_base_vect_type) res = zdotc(n,x%v,1,y%v,1) class default res = y%dot(n,x%v) end select end function z_base_dot_v ! ! Base workhorse is good old BLAS1 ! function z_base_dot_a(n,x,y) result(res) implicit none class(psb_z_base_vect_type), intent(inout) :: x complex(psb_dpk_), intent(in) :: y(:) integer(psb_ipk_), intent(in) :: n complex(psb_dpk_) :: res complex(psb_dpk_), external :: zdotc res = zdotc(n,y,1,x%v,1) end function z_base_dot_a ! ! AXPBY is invoked via Y, hence the structure below. ! subroutine z_base_axpby_v(m,alpha, x, beta, y, info) use psi_serial_mod implicit none integer(psb_ipk_), intent(in) :: m class(psb_z_base_vect_type), intent(inout) :: x class(psb_z_base_vect_type), intent(inout) :: y complex(psb_dpk_), intent (in) :: alpha, beta integer(psb_ipk_), intent(out) :: info select type(xx => x) type is (psb_z_base_vect_type) call psb_geaxpby(m,alpha,x%v,beta,y%v,info) class default call y%axpby(m,alpha,x%v,beta,info) end select end subroutine z_base_axpby_v subroutine z_base_axpby_a(m,alpha, x, beta, y, info) use psi_serial_mod implicit none integer(psb_ipk_), intent(in) :: m complex(psb_dpk_), intent(in) :: x(:) class(psb_z_base_vect_type), intent(inout) :: y complex(psb_dpk_), intent (in) :: alpha, beta integer(psb_ipk_), intent(out) :: info call psb_geaxpby(m,alpha,x,beta,y%v,info) end subroutine z_base_axpby_a ! ! Multiple variants of two operations: ! Simple multiplication Y(:) = X(:)*Y(:) ! blas-like: Z(:) = alpha*X(:)*Y(:)+beta*Z(:) ! ! Variants expanded according to the dynamic type ! of the involved entities ! subroutine z_base_mlt_v(x, y, info) use psi_serial_mod implicit none class(psb_z_base_vect_type), intent(inout) :: x class(psb_z_base_vect_type), intent(inout) :: y integer(psb_ipk_), intent(out) :: info integer(psb_ipk_) :: i, n info = 0 select type(xx => x) type is (psb_z_base_vect_type) n = min(size(y%v), size(xx%v)) do i=1, n y%v(i) = y%v(i)*xx%v(i) end do class default call y%mlt(x%v,info) end select end subroutine z_base_mlt_v subroutine z_base_mlt_a(x, y, info) use psi_serial_mod implicit none complex(psb_dpk_), intent(in) :: x(:) class(psb_z_base_vect_type), intent(inout) :: y integer(psb_ipk_), intent(out) :: info integer(psb_ipk_) :: i, n info = 0 n = min(size(y%v), size(x)) do i=1, n y%v(i) = y%v(i)*x(i) end do end subroutine z_base_mlt_a subroutine z_base_mlt_a_2(alpha,x,y,beta,z,info) use psi_serial_mod implicit none complex(psb_dpk_), intent(in) :: alpha,beta complex(psb_dpk_), intent(in) :: y(:) complex(psb_dpk_), intent(in) :: x(:) class(psb_z_base_vect_type), intent(inout) :: z integer(psb_ipk_), intent(out) :: info integer(psb_ipk_) :: i, n info = 0 n = min(size(z%v), size(x), size(y)) !!$ write(0,*) 'Mlt_a_2: ',n if (alpha == zzero) then if (beta == zone) then return else do i=1, n z%v(i) = beta*z%v(i) end do end if else if (alpha == zone) then if (beta == zzero) then do i=1, n z%v(i) = y(i)*x(i) end do else if (beta == zone) then do i=1, n z%v(i) = z%v(i) + y(i)*x(i) end do else do i=1, n z%v(i) = beta*z%v(i) + y(i)*x(i) end do end if else if (alpha == -zone) then if (beta == zzero) then do i=1, n z%v(i) = -y(i)*x(i) end do else if (beta == zone) then do i=1, n z%v(i) = z%v(i) - y(i)*x(i) end do else do i=1, n z%v(i) = beta*z%v(i) - y(i)*x(i) end do end if else if (beta == zzero) then do i=1, n z%v(i) = alpha*y(i)*x(i) end do else if (beta == zone) then do i=1, n z%v(i) = z%v(i) + alpha*y(i)*x(i) end do else do i=1, n z%v(i) = beta*z%v(i) + alpha*y(i)*x(i) end do end if end if end if end subroutine z_base_mlt_a_2 subroutine z_base_mlt_v_2(alpha,x,y,beta,z,info,conjgx,conjgy) use psi_serial_mod use psb_string_mod implicit none complex(psb_dpk_), intent(in) :: alpha,beta class(psb_z_base_vect_type), intent(inout) :: x class(psb_z_base_vect_type), intent(inout) :: y class(psb_z_base_vect_type), intent(inout) :: z integer(psb_ipk_), intent(out) :: info character(len=1), intent(in), optional :: conjgx, conjgy integer(psb_ipk_) :: i, n logical :: conjgx_, conjgy_ info = 0 if (.not.psb_z_is_complex_) then call z%mlt(alpha,x%v,y%v,beta,info) else conjgx_=.false. if (present(conjgx)) conjgx_ = (psb_toupper(conjgx)=='C') conjgy_=.false. if (present(conjgy)) conjgy_ = (psb_toupper(conjgy)=='C') if (conjgx_) x%v=conjg(x%v) if (conjgy_) y%v=conjg(y%v) call z%mlt(alpha,x%v,y%v,beta,info) if (conjgx_) x%v=conjg(x%v) if (conjgy_) y%v=conjg(y%v) end if end subroutine z_base_mlt_v_2 subroutine z_base_mlt_av(alpha,x,y,beta,z,info) use psi_serial_mod implicit none complex(psb_dpk_), intent(in) :: alpha,beta complex(psb_dpk_), intent(in) :: x(:) class(psb_z_base_vect_type), intent(inout) :: y class(psb_z_base_vect_type), intent(inout) :: z integer(psb_ipk_), intent(out) :: info integer(psb_ipk_) :: i, n info = 0 call z%mlt(alpha,x,y%v,beta,info) end subroutine z_base_mlt_av subroutine z_base_mlt_va(alpha,x,y,beta,z,info) use psi_serial_mod implicit none complex(psb_dpk_), intent(in) :: alpha,beta complex(psb_dpk_), intent(in) :: y(:) class(psb_z_base_vect_type), intent(inout) :: x class(psb_z_base_vect_type), intent(inout) :: z integer(psb_ipk_), intent(out) :: info integer(psb_ipk_) :: i, n info = 0 call z%mlt(alpha,y,x,beta,info) end subroutine z_base_mlt_va ! ! Simple scaling ! subroutine z_base_scal(alpha, x) use psi_serial_mod implicit none class(psb_z_base_vect_type), intent(inout) :: x complex(psb_dpk_), intent (in) :: alpha if (allocated(x%v)) x%v = alpha*x%v end subroutine z_base_scal ! ! Norms 1, 2 and infinity ! function z_base_nrm2(n,x) result(res) implicit none class(psb_z_base_vect_type), intent(inout) :: x integer(psb_ipk_), intent(in) :: n real(psb_dpk_) :: res real(psb_dpk_), external :: dznrm2 res = dznrm2(n,x%v,1) end function z_base_nrm2 function z_base_amax(n,x) result(res) implicit none class(psb_z_base_vect_type), intent(inout) :: x integer(psb_ipk_), intent(in) :: n real(psb_dpk_) :: res res = maxval(abs(x%v(1:n))) end function z_base_amax function z_base_asum(n,x) result(res) implicit none class(psb_z_base_vect_type), intent(inout) :: x integer(psb_ipk_), intent(in) :: n real(psb_dpk_) :: res res = sum(abs(x%v(1:n))) end function z_base_asum ! ! Gather: Y = beta * Y + alpha * X(IDX(:)) ! subroutine z_base_gthab(n,idx,alpha,x,beta,y) use psi_serial_mod integer(psb_ipk_) :: n, idx(:) complex(psb_dpk_) :: alpha, beta, y(:) class(psb_z_base_vect_type) :: x call x%sync() call psi_gth(n,idx,alpha,x%v,beta,y) end subroutine z_base_gthab ! ! shortcut alpha=1 beta=0 ! subroutine z_base_gthzv(n,idx,x,y) use psi_serial_mod integer(psb_ipk_) :: n, idx(:) complex(psb_dpk_) :: y(:) class(psb_z_base_vect_type) :: x call x%sync() call psi_gth(n,idx,x%v,y) end subroutine z_base_gthzv ! ! Scatter: ! Y(IDX(:)) = beta*Y(IDX(:)) + X(:) ! subroutine z_base_sctb(n,idx,x,beta,y) use psi_serial_mod integer(psb_ipk_) :: n, idx(:) complex(psb_dpk_) :: beta, x(:) class(psb_z_base_vect_type) :: y call y%sync() call psi_sct(n,idx,x,beta,y%v) call y%set_host() end subroutine z_base_sctb end module psb_z_base_vect_mod