Beispiel #1
0
    def __init__(self, A, lib, **kwargs):
        try:
            self.dense = isinstance(A, ndarray) and len(A.shape) == 2
            self.CSC = isinstance(A, csc_matrix)
            self.CSR = isinstance(A, csr_matrix)

            assert self.dense or self.CSC or self.CSR
            assert A.dtype == c_float or A.dtype == c_double

            self.m = A.shape[0]
            self.n = A.shape[1]
            self.A = A
            self.lib = lib
            self.wDev = 0

            self.double_precision = A.dtype == c_double
            self.settings = make_settings(self.double_precision, **kwargs)
            self.pysolution = Solution(self.double_precision, self.m, self.n)
            self.solution = make_solution(self.pysolution)
            self.info = make_info(self.double_precision)
            self.order = H2OConstants.ROW_MAJ if (self.CSR or self.dense) \
                else H2OConstants.COL_MAJ

            if self.dense and not self.double_precision:
                self.work = self.lib.h2o4gpu_init_dense_single(
                    self.wDev, self.order, self.m, self.n, cptr(A, c_float))
            elif self.dense:
                self.work = self.lib.h2o4gpu_init_dense_double(
                    self.wDev, self.order, self.m, self.n, cptr(A, c_double))
            elif not self.double_precision:
                self.work = self.lib.h2o4gpu_init_sparse_single(
                    self.wDev, self.order, self.m, self.n, A.nnz,
                    cptr(A.data, c_float), cptr(A.indices, c_int),
                    cptr(A.indptr, c_int))
            else:
                self.work = self.lib.h2o4gpu_init_sparse_double(
                    self.wDev, self.order, self.m, self.n, A.nnz,
                    cptr(A.data, c_double), cptr(A.indices, c_int),
                    cptr(A.indptr, c_int))

        except AssertionError:
            print("Data must be a (m x n) numpy ndarray or scipy csc_matrix "
                  "containing float32 or float64 values")
Beispiel #2
0
    def __init__(self, A, lib, **kwargs):
        try:
            self.dense = isinstance(A, ndarray) and len(A.shape) == 2
            self.CSC = isinstance(A, csc_matrix)
            self.CSR = isinstance(A, csr_matrix)

            assert self.dense or self.CSC or self.CSR
            assert A.dtype == c_float or A.dtype == c_double

            self.m = A.shape[0]
            self.n = A.shape[1]
            self.A = A
            self.lib = lib
            self.wDev = 0

            self.double_precision = A.dtype == c_double
            self.settings = make_settings(self.double_precision, **kwargs)
            self.pysolution = Solution(self.double_precision, self.m, self.n)
            self.solution = make_solution(self.pysolution)
            self.info = make_info(self.double_precision)
            self.order = H2OConstants.ROW_MAJ if (self.CSR or self.dense) \
                else H2OConstants.COL_MAJ

            if self.dense and not self.double_precision:
                self.work = self.lib.h2o4gpu_init_dense_single(
                    self.wDev, self.order, self.m, self.n, cptr(A, c_float))
            elif self.dense:
                self.work = self.lib.h2o4gpu_init_dense_double(
                    self.wDev, self.order, self.m, self.n, cptr(A, c_double))
            elif not self.double_precision:
                self.work = self.lib.h2o4gpu_init_sparse_single(
                    self.wDev, self.order, self.m, self.n, A.nnz,
                    cptr(A.data, c_float),
                    cptr(A.indices, c_int), cptr(A.indptr, c_int))
            else:
                self.work = self.lib.h2o4gpu_init_sparse_double(
                    self.wDev, self.order, self.m, self.n, A.nnz,
                    cptr(A.data, c_double),
                    cptr(A.indices, c_int), cptr(A.indptr, c_int))

        except AssertionError:
            print("Data must be a (m x n) numpy ndarray or scipy csc_matrix "
                  "containing float32 or float64 values")
Beispiel #3
0
def _convert_to_ptr(data):
    """Convert data to a form which can be passed to C/C++ code.

    :param data: array_like
    :return:
    """

    if data is not None:
        np_data, _, dtype = _to_np(data)
        if dtype == np.float32:
            c_ftype = c_float
        elif dtype == np.float64:
            c_ftype = c_double
        else:
            ValueError("No such dtype")
        data_ptr = cptr(np_data, dtype=c_ftype)
    else:
        data_ptr = None

    return data_ptr
Beispiel #4
0
def _convert_to_ptr(data):
    """Convert data to a form which can be passed to C/C++ code.

    :param data: array_like
    :return:
    """

    if data is not None:
        np_data, _, dtype = _to_np(data)
        if dtype == np.float32:
            c_ftype = c_float
        elif dtype == np.float64:
            c_ftype = c_double
        else:
            ValueError("No such dtype")
        data_ptr = cptr(np_data, dtype=c_ftype)
    else:
        data_ptr = None

    return data_ptr
Beispiel #5
0
    def fit(self, f, g, **kwargs):
        try:
            # assert f,g types
            assert isinstance(f, FunctionVector)
            assert isinstance(g, FunctionVector)

            # assert f,g lengths
            assert f.length() == self.m
            assert g.length() == self.n

            # pass previous rho through, if not first run (rho=0)
            if self.info.rho > 0:
                self.settings.rho = self.info.rho

            # apply user inputs
            change_settings(self.settings, **kwargs)
            change_solution(self.pysolution, **kwargs)

            if not self.work:
                print("No viable H2O4GPU_work pointer to call solve()."
                      "Call Solver.init( args... ) first")
                return
            elif not self.double_precision:
                self.lib.h2o4gpu_solve_single(self.work,
                                              pointer(self.settings),
                                              pointer(self.solution),
                                              pointer(self.info),
                                              cptr(f.a, c_float),
                                              cptr(f.b, c_float),
                                              cptr(f.c, c_float),
                                              cptr(f.d, c_float),
                                              cptr(f.e, c_float),
                                              cptr(f.h, c_int),
                                              cptr(g.a, c_float),
                                              cptr(g.b, c_float),
                                              cptr(g.c, c_float),
                                              cptr(g.d, c_float),
                                              cptr(g.e, c_float),
                                              cptr(g.h, c_int))
            else:
                self.lib.h2o4gpu_solve_double(self.work,
                                              pointer(self.settings),
                                              pointer(self.solution),
                                              pointer(self.info),
                                              cptr(f.a, c_double),
                                              cptr(f.b, c_double),
                                              cptr(f.c, c_double),
                                              cptr(f.d, c_double),
                                              cptr(f.e, c_double),
                                              cptr(f.h, c_int),
                                              cptr(g.a, c_double),
                                              cptr(g.b, c_double),
                                              cptr(g.c, c_double),
                                              cptr(g.d, c_double),
                                              cptr(g.e, c_double),
                                              cptr(g.h, c_int))

        except AssertionError:
            print("\nf and g must be objects of type FunctionVector with:")
            print(">length of f = m, # of rows in solver's data matrix A")
            print(">length of g = n, # of columns in solver's data matrix A")
Beispiel #6
0
    def fit(self, f, g, **kwargs):
        try:
            # assert f,g types
            assert isinstance(f, FunctionVector)
            assert isinstance(g, FunctionVector)

            # assert f,g lengths
            assert f.length() == self.m
            assert g.length() == self.n

            # pass previous rho through, if not first run (rho=0)
            if self.info.rho > 0:
                self.settings.rho = self.info.rho

            # apply user inputs
            change_settings(self.settings, **kwargs)
            change_solution(self.pysolution, **kwargs)

            if not self.work:
                print("No viable H2O4GPU_work pointer to call solve()."
                      "Call Solver.init( args... ) first")
                return
            elif not self.double_precision:
                self.lib.h2o4gpu_solve_single(self.work,
                                              pointer(self.settings),
                                              pointer(self.solution),
                                              pointer(self.info),
                                              cptr(f.a, c_float),
                                              cptr(f.b, c_float),
                                              cptr(f.c, c_float),
                                              cptr(f.d, c_float),
                                              cptr(f.e, c_float),
                                              cptr(f.h, c_int),
                                              cptr(g.a, c_float),
                                              cptr(g.b, c_float),
                                              cptr(g.c, c_float),
                                              cptr(g.d, c_float),
                                              cptr(g.e, c_float),
                                              cptr(g.h, c_int))
            else:
                self.lib.h2o4gpu_solve_double(self.work,
                                              pointer(self.settings),
                                              pointer(self.solution),
                                              pointer(self.info),
                                              cptr(f.a, c_double),
                                              cptr(f.b, c_double),
                                              cptr(f.c, c_double),
                                              cptr(f.d, c_double),
                                              cptr(f.e, c_double),
                                              cptr(f.h, c_int),
                                              cptr(g.a, c_double),
                                              cptr(g.b, c_double),
                                              cptr(g.c, c_double),
                                              cptr(g.d, c_double),
                                              cptr(g.e, c_double),
                                              cptr(g.h, c_int))

        except AssertionError:
            print("\nf and g must be objects of type FunctionVector with:")
            print(">length of f = m, # of rows in solver's data matrix A")
            print(">length of g = n, # of columns in solver's data matrix A")