python-linop 0.8.2-3 / usr / lib / python2.7 / dist-packages / linop / blkop.py

#Copyright (c) 2008-2013, Dominique Orban <dominique.orban@gerad.ca>
#All rights reserved.
#
#Copyright (c) 2013-2014, Ghislain Vaillant <ghisvail@gmail.com>
#All rights reserved.
#
#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. Neither the name of the linop developers nor the names of any contributors
#   may be used to endorse or promote products derived from this software
#   without specific prior written permission.
#
#THIS SOFTWARE IS PROVIDED BY THE REGENTS 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 REGENTS OR 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.

from .linop import BaseLinearOperator, LinearOperator
from .linop import ShapeError, null_log
import numpy as np
import itertools
from functools import reduce


class BlockLinearOperator(LinearOperator):

    """
    A linear operator defined by blocks. Each block must be a linear operator.

    `blocks` should be a list of lists describing the blocks row-wise.
    If there is only one block row, it should be specified as
    `[[b1, b2, ..., bn]]`, not as `[b1, b2, ..., bn]`.

    If the overall linear operator is symmetric, only its upper triangle
    need be specified, e.g., `[[A,B,C], [D,E], [F]]`, and the blocks on the
    diagonal must be square and symmetric.

    """

    def __init__(self, blocks, symmetric=False, **kwargs):
        # If building a symmetric operator, fill in the blanks.
        # They're just references to existing objects.
        try:
            for block_row in blocks:
                for block_col in block_row:
                    op_shape = block_col.shape
        except (TypeError, AttributeError):
            raise ValueError('blocks should be a nested list of operators')

        if symmetric:
            nrow = len(blocks)
            ncol = len(blocks[0])
            if nrow != ncol:
                raise ShapeError('Inconsistent shape.')

            for block_row in blocks:
                if not block_row[0].symmetric:
                    raise ValueError('Blocks on diagonal must be symmetric.')

            self._blocks = blocks[:]
            for i in range(1, nrow):
                for j in range(i - 1, -1, -1):
                    self._blocks[i].insert(0, self._blocks[j][i].T)

        else:
            self._blocks = blocks

        log = kwargs.get('logger', null_log)
        log.debug('Building new BlockLinearOperator')

        nargins = [[blk.shape[-1] for blk in row] for row in self._blocks]
        log.debug('nargins = ' + repr(nargins))
        nargins_by_row = [nargin[0] for nargin in nargins]
        if min(nargins_by_row) != max(nargins_by_row):
            raise ShapeError('Inconsistent block shapes')

        nargouts = [[blk.shape[0] for blk in row] for row in self._blocks]
        log.debug('nargouts = ' + repr(nargouts))
        for row in nargouts:
            if min(row) != max(row):
                raise ShapeError('Inconsistent block shapes')

        nargin = sum(nargins[0])
        nargout = sum([out[0] for out in nargouts])

        # Create blocks of transpose operator.
        blocksT = list(map(lambda *row: [blk.T for blk in row], *self._blocks))

        def blk_matvec(x, blks):
            nargins = [[blk.shape[-1] for blk in blkrow] for blkrow in blks]
            nargouts = [[blk.shape[0] for blk in blkrow] for blkrow in blks]
            nargin = sum(nargins[0])
            nargout = sum([out[0] for out in nargouts])
            nx = len(x)
            self.logger.debug('Multiplying with a vector of size %d' % nx)
            self.logger.debug('nargin=%d, nargout=%d' % (nargin, nargout))
            if nx != nargin:
                raise ShapeError('Multiplying with vector of wrong shape.')

            result_type = np.result_type(self.dtype, x.dtype)
            y = np.zeros(nargout, dtype=result_type)

            nblk_row = len(blks)
            nblk_col = len(blks[0])

            row_start = col_start = 0
            for row in range(nblk_row):
                row_end = row_start + nargouts[row][0]
                yout = y[row_start:row_end]
                for col in range(nblk_col):
                    col_end = col_start + nargins[0][col]
                    xin = x[col_start:col_end]
                    B = blks[row][col]
                    yout[:] += B * xin
                    col_start = col_end
                row_start = row_end
                col_start = 0

            return y

        flat_blocks = list(itertools.chain(*blocks))
        blk_dtypes = [blk.dtype for blk in flat_blocks]
        op_dtype = np.result_type(*blk_dtypes)

        super(BlockLinearOperator, self).__init__(
            nargin, nargout,
            symmetric=symmetric,
            matvec=lambda x: blk_matvec(x, self._blocks),
            rmatvec=lambda x: blk_matvec(x, blocksT),
            dtype=op_dtype,
            **kwargs)

        self.H._blocks = blocksT

    @property
    def blocks(self):
        """The list of blocks defining the block operator."""
        return self._blocks

    def __getitem__(self, indices):
        blks = np.matrix(self._blocks, dtype=object)[indices]
        # If indexing narrowed it down to a single block, return it.
        if isinstance(blks, BaseLinearOperator):
            return blks
        # Otherwise, we have a matrix of blocks.
        return BlockLinearOperator(blks.tolist(), symmetric=False)

    def __contains__(self, op):
        flat_blocks = list(itertools.chain(*self.blocks))
        return op in flat_blocks

    def __iter__(self):
        for block in self._blocks:
            yield block


class BlockDiagonalLinearOperator(LinearOperator):

    """
    A block diagonal linear operator.

    Each block must be a linear operator.
    The blocks may be specified as one list, e.g., `[A, B, C]`.

    """

    def __init__(self, blocks, **kwargs):

        try:
            for block in blocks:
                op_shape = block.shape
        except (TypeError, AttributeError):
            raise ValueError('blocks should be a flattened list of operators')

        symmetric = reduce(
            lambda x, y: x and y, [blk.symmetric for blk in blocks])

        self._blocks = blocks

        log = kwargs.get('logger', null_log)
        log.debug('Building new BlockDiagonalLinearOperator')

        nargins = [blk.shape[-1] for blk in blocks]
        log.debug('nargins = ' + repr(nargins))

        nargouts = [blk.shape[0] for blk in blocks]
        log.debug('nargouts = ' + repr(nargouts))

        nargin = sum(nargins)
        nargout = sum(nargouts)

        # Create blocks of transpose operator.
        blocksT = [blk.T for blk in blocks]

        def blk_matvec(x, blks):
            nx = len(x)
            nargins = [blk.shape[-1] for blk in blocks]
            nargin = sum(nargins)
            nargouts = [blk.shape[0] for blk in blocks]
            nargout = sum(nargouts)
            self.logger.debug('Multiplying with a vector of size %d' % nx)
            self.logger.debug('nargin=%d, nargout=%d' % (nargin, nargout))
            if nx != nargin:
                raise ShapeError('Multiplying with vector of wrong shape.')

            result_type = np.result_type(self.dtype, x.dtype)
            y = np.empty(nargout, dtype=result_type)

            nblks = len(blks)

            row_start = col_start = 0
            for blk in range(nblks):
                row_end = row_start + nargouts[blk]
                yout = y[row_start:row_end]

                col_end = col_start + nargins[blk]
                xin = x[col_start:col_end]

                B = blks[blk]
                yout[:] = B * xin

                col_start = col_end
                row_start = row_end

            return y

        blk_dtypes = [blk.dtype for blk in blocks]
        op_dtype = np.result_type(*blk_dtypes)

        super(BlockDiagonalLinearOperator, self).__init__(
            nargin, nargout,
            symmetric=symmetric,
            matvec=lambda x: blk_matvec(x, self._blocks),
            rmatvec=lambda x: blk_matvec(x, blocksT),
            dtype=op_dtype,
            **kwargs)

        self.H._blocks = blocksT

    @property
    def blocks(self):
        """The list of blocks defining the block diagonal operator."""
        return self._blocks

    def __getitem__(self, idx):
        blks = self._blocks[idx]
        if isinstance(idx, slice):
            return BlockDiagonalLinearOperator(blks, symmetric=self.symmetric)
        return blks

    def __setitem__(self, idx, ops):
        if not isinstance(ops, BaseLinearOperator):
            if isinstance(ops, list) or isinstance(ops, tuple):
                for op in ops:
                    if not isinstance(op, BaseLinearOperator):
                        msg = 'Block operators can only contain'
                        msg += ' linear operators'
                        raise ValueError(msg)
        self._blocks[idx] = ops


class BlockPreconditioner(BlockLinearOperator):

    """An alias for ``BlockLinearOperator``.

    Holds an additional ``solve`` method equivalent to ``__mul__``.

    """

    def solve(self, x):
        """An alias to __call__."""
        return self.__call__(x)


class BlockDiagonalPreconditioner(BlockDiagonalLinearOperator):

    """
    An alias for ``BlockDiagonalLinearOperator``.

    Holds an additional ``solve`` method equivalent to ``__mul__``.

    """

    def solve(self, x):
        """An alias to __call__."""
        return self.__call__(x)


class BlockHorizontalLinearOperator(BlockLinearOperator):

    """
    A block horizontal linear operator.

    Each block must be a linear operator.
    The blocks must be specified as one list, e.g., `[A, B, C]`.

    """

    def __init__(self, blocks, **kwargs):

        try:
            for block in blocks:
                op_shape = block.shape
        except (TypeError, AttributeError):
            raise ValueError('blocks should be a flattened list of operators')

        blocks=[[blk for blk in blocks]]

        super(BlockHorizontalLinearOperator, self).__init__(
            blocks=blocks, symmetric=False, **kwargs)


class BlockVerticalLinearOperator(BlockLinearOperator):

    """
    A block vertical linear operator.

    Each block must be a linear operator.
    The blocks must be specified as one list, e.g., `[A, B, C]`.

    """

    def __init__(self, blocks, **kwargs):

        try:
            for block in blocks:
                op_shape = block.shape
        except (TypeError, AttributeError):
            raise ValueError('blocks should be a flattened list of operators')

        blocks=[[blk] for blk in blocks]

        super(BlockVerticalLinearOperator, self).__init__(
            blocks=blocks, symmetric=False, **kwargs)


# some shorter aliases
BlockOperator = BlockLinearOperator
BlockDiagonalOperator = BlockDiagonalLinearOperator
BlockHorizontalOperator = BlockHorizontalLinearOperator
BlockVerticalOperator = BlockVerticalLinearOperator