tensor.py

from textwrap import indent
from typing import Any, Dict, List, Optional, Tuple, Union

import numpy as np
import scipy.sparse
import torch
from torch_scatter import segment_csr

from torch_sparse.storage import SparseStorage, get_layout


@torch.jit.script
class SparseTensor(object):
    storage: SparseStorage

    def __init__(
        self,
        row: Optional[torch.Tensor] = None,
        rowptr: Optional[torch.Tensor] = None,
        col: Optional[torch.Tensor] = None,
        value: Optional[torch.Tensor] = None,
        sparse_sizes: Optional[Tuple[Optional[int], Optional[int]]] = None,
        is_sorted: bool = False,
        trust_data: bool = False,
    ):
        self.storage = SparseStorage(
            row=row,
            rowptr=rowptr,
            col=col,
            value=value,
            sparse_sizes=sparse_sizes,
            rowcount=None,
            colptr=None,
            colcount=None,
            csr2csc=None,
            csc2csr=None,
            is_sorted=is_sorted,
            trust_data=trust_data,
        )

    @classmethod
    def from_storage(self, storage: SparseStorage):
        out = SparseTensor(
            row=storage._row,
            rowptr=storage._rowptr,
            col=storage._col,
            value=storage._value,
            sparse_sizes=storage._sparse_sizes,
            is_sorted=True,
            trust_data=True,
        )
        out.storage._rowcount = storage._rowcount
        out.storage._colptr = storage._colptr
        out.storage._colcount = storage._colcount
        out.storage._csr2csc = storage._csr2csc
        out.storage._csc2csr = storage._csc2csr
        return out

    @classmethod
    def from_edge_index(
        self,
        edge_index: torch.Tensor,
        edge_attr: Optional[torch.Tensor] = None,
        sparse_sizes: Optional[Tuple[Optional[int], Optional[int]]] = None,
        is_sorted: bool = False,
        trust_data: bool = False,
    ):
        return SparseTensor(
            row=edge_index[0],
            rowptr=None,
            col=edge_index[1],
            value=edge_attr,
            sparse_sizes=sparse_sizes,
            is_sorted=is_sorted,
            trust_data=trust_data,
        )

    @classmethod
    def from_dense(self, mat: torch.Tensor, has_value: bool = True):
        if mat.dim() > 2:
            index = mat.abs().sum([i for i in range(2, mat.dim())]).nonzero()
        else:
            index = mat.nonzero()
        index = index.t()

        row = index[0]
        col = index[1]

        value: Optional[torch.Tensor] = None
        if has_value:
            value = mat[row, col]

        return SparseTensor(
            row=row,
            rowptr=None,
            col=col,
            value=value,
            sparse_sizes=(mat.size(0), mat.size(1)),
            is_sorted=True,
            trust_data=True,
        )

    @classmethod
    def from_torch_sparse_coo_tensor(
        self,
        mat: torch.Tensor,
        has_value: bool = True,
    ):
        mat = mat.coalesce()
        index = mat._indices()
        row, col = index[0], index[1]

        value: Optional[torch.Tensor] = None
        if has_value:
            value = mat.values()

        return SparseTensor(
            row=row,
            rowptr=None,
            col=col,
            value=value,
            sparse_sizes=(mat.size(0), mat.size(1)),
            is_sorted=True,
            trust_data=True,
        )

    @classmethod
    def from_torch_sparse_csr_tensor(
        self,
        mat: torch.Tensor,
        has_value: bool = True,
    ):
        rowptr = mat.crow_indices()
        col = mat.col_indices()

        value: Optional[torch.Tensor] = None
        if has_value:
            value = mat.values()

        return SparseTensor(
            row=None,
            rowptr=rowptr,
            col=col,
            value=value,
            sparse_sizes=(mat.size(0), mat.size(1)),
            is_sorted=True,
            trust_data=True,
        )

    @classmethod
    def eye(self,
            M: int,
            N: Optional[int] = None,
            has_value: bool = True,
            dtype: Optional[int] = None,
            device: Optional[torch.device] = None,
            fill_cache: bool = False):

        N = M if N is None else N

        row = torch.arange(min(M, N), device=device)
        col = row

        rowptr = torch.arange(M + 1, device=row.device)
        if M > N:
            rowptr[N + 1:] = N

        value: Optional[torch.Tensor] = None
        if has_value:
            value = torch.ones(row.numel(), dtype=dtype, device=row.device)

        rowcount: Optional[torch.Tensor] = None
        colptr: Optional[torch.Tensor] = None
        colcount: Optional[torch.Tensor] = None
        csr2csc: Optional[torch.Tensor] = None
        csc2csr: Optional[torch.Tensor] = None

        if fill_cache:
            rowcount = torch.ones(M, dtype=torch.long, device=row.device)
            if M > N:
                rowcount[N:] = 0

            colptr = torch.arange(N + 1, dtype=torch.long, device=row.device)
            colcount = torch.ones(N, dtype=torch.long, device=row.device)
            if N > M:
                colptr[M + 1:] = M
                colcount[M:] = 0
            csr2csc = csc2csr = row

        out = SparseTensor(
            row=row,
            rowptr=rowptr,
            col=col,
            value=value,
            sparse_sizes=(M, N),
            is_sorted=True,
            trust_data=True,
        )
        out.storage._rowcount = rowcount
        out.storage._colptr = colptr
        out.storage._colcount = colcount
        out.storage._csr2csc = csr2csc
        out.storage._csc2csr = csc2csr
        return out

    def copy(self):
        return self.from_storage(self.storage)

    def clone(self):
        return self.from_storage(self.storage.clone())

    def type(self, dtype: torch.dtype, non_blocking: bool = False):
        value = self.storage.value()
        if value is None or dtype == value.dtype:
            return self
        return self.from_storage(
            self.storage.type(dtype=dtype, non_blocking=non_blocking))

    def type_as(self, tensor: torch.Tensor, non_blocking: bool = False):
        return self.type(dtype=tensor.dtype, non_blocking=non_blocking)

    def to_device(self, device: torch.device, non_blocking: bool = False):
        if device == self.device():
            return self
        return self.from_storage(
            self.storage.to_device(device=device, non_blocking=non_blocking))

    def device_as(self, tensor: torch.Tensor, non_blocking: bool = False):
        return self.to_device(device=tensor.device, non_blocking=non_blocking)

    # Formats #################################################################

    def coo(self) -> Tuple[torch.Tensor, torch.Tensor, Optional[torch.Tensor]]:
        return self.storage.row(), self.storage.col(), self.storage.value()

    def csr(self) -> Tuple[torch.Tensor, torch.Tensor, Optional[torch.Tensor]]:
        return self.storage.rowptr(), self.storage.col(), self.storage.value()

    def csc(self) -> Tuple[torch.Tensor, torch.Tensor, Optional[torch.Tensor]]:
        perm = self.storage.csr2csc()
        value = self.storage.value()
        if value is not None:
            value = value[perm]
        return self.storage.colptr(), self.storage.row()[perm], value

    # Storage inheritance #####################################################

    def has_value(self) -> bool:
        return self.storage.has_value()

    def set_value_(
        self,
        value: Optional[torch.Tensor],
        layout: Optional[str] = None,
    ):
        self.storage.set_value_(value, layout)
        return self

    def set_value(
        self,
        value: Optional[torch.Tensor],
        layout: Optional[str] = None,
    ):
        return self.from_storage(self.storage.set_value(value, layout))

    def sparse_sizes(self) -> Tuple[int, int]:
        return self.storage.sparse_sizes()

    def sparse_size(self, dim: int) -> int:
        return self.storage.sparse_sizes()[dim]

    def sparse_resize(self, sparse_sizes: Tuple[int, int]):
        return self.from_storage(self.storage.sparse_resize(sparse_sizes))

    def sparse_reshape(self, num_rows: int, num_cols: int):
        return self.from_storage(
            self.storage.sparse_reshape(num_rows, num_cols))

    def is_coalesced(self) -> bool:
        return self.storage.is_coalesced()

    def coalesce(self, reduce: str = "sum"):
        return self.from_storage(self.storage.coalesce(reduce))

    def fill_cache_(self):
        self.storage.fill_cache_()
        return self

    def clear_cache_(self):
        self.storage.clear_cache_()
        return self

    def __eq__(self, other) -> bool:
        if not isinstance(other, self.__class__):
            return False

        if self.sizes() != other.sizes():
            return False

        rowptrA, colA, valueA = self.csr()
        rowptrB, colB, valueB = other.csr()

        if valueA is None and valueB is not None:
            return False
        if valueA is not None and valueB is None:
            return False
        if not torch.equal(rowptrA, rowptrB):
            return False
        if not torch.equal(colA, colB):
            return False
        if valueA is None and valueB is None:
            return True
        return torch.equal(valueA, valueB)

    # Utility functions #######################################################

    def fill_value_(self, fill_value: float, dtype: Optional[int] = None):
        value = torch.full(
            (self.nnz(), ),
            fill_value,
            dtype=dtype,
            device=self.device(),
        )
        return self.set_value_(value, layout='coo')

    def fill_value(self, fill_value: float, dtype: Optional[int] = None):
        value = torch.full(
            (self.nnz(), ),
            fill_value,
            dtype=dtype,
            device=self.device(),
        )
        return self.set_value(value, layout='coo')

    def sizes(self) -> List[int]:
        sparse_sizes = self.sparse_sizes()
        value = self.storage.value()
        if value is not None:
            return list(sparse_sizes) + list(value.size())[1:]
        else:
            return list(sparse_sizes)

    def size(self, dim: int) -> int:
        return self.sizes()[dim]

    def dim(self) -> int:
        return len(self.sizes())

    def nnz(self) -> int:
        return self.storage.col().numel()

    def numel(self) -> int:
        value = self.storage.value()
        if value is not None:
            return value.numel()
        else:
            return self.nnz()

    def density(self) -> float:
        if self.sparse_size(0) == 0 or self.sparse_size(1) == 0:
            return 0.0
        return self.nnz() / (self.sparse_size(0) * self.sparse_size(1))

    def sparsity(self) -> float:
        return 1 - self.density()

    def avg_row_length(self) -> float:
        return self.nnz() / self.sparse_size(0)

    def avg_col_length(self) -> float:
        return self.nnz() / self.sparse_size(1)

    def bandwidth(self) -> int:
        row, col, _ = self.coo()
        return int((row - col).abs_().max())

    def avg_bandwidth(self) -> float:
        row, col, _ = self.coo()
        return float((row - col).abs_().to(torch.float).mean())

    def bandwidth_proportion(self, bandwidth: int) -> float:
        row, col, _ = self.coo()
        tmp = (row - col).abs_()
        return int((tmp <= bandwidth).sum()) / self.nnz()

    def is_quadratic(self) -> bool:
        return self.sparse_size(0) == self.sparse_size(1)

    def is_symmetric(self) -> bool:
        if not self.is_quadratic():
            return False

        rowptr, col, value1 = self.csr()
        colptr, row, value2 = self.csc()

        if (rowptr != colptr).any() or (col != row).any():
            return False

        if value1 is None or value2 is None:
            return True
        else:
            return bool((value1 == value2).all())

    def to_symmetric(self, reduce: str = "sum"):
        N = max(self.size(0), self.size(1))

        row, col, value = self.coo()
        idx = col.new_full((2 * col.numel() + 1, ), -1)
        idx[1:row.numel() + 1] = row
        idx[row.numel() + 1:] = col
        idx[1:] *= N
        idx[1:row.numel() + 1] += col
        idx[row.numel() + 1:] += row

        idx, perm = idx.sort()
        mask = idx[1:] > idx[:-1]
        perm = perm[1:].sub_(1)
        idx = perm[mask]

        if value is not None:
            ptr = mask.nonzero().flatten()
            ptr = torch.cat([ptr, ptr.new_full((1, ), perm.size(0))])
            value = torch.cat([value, value])[perm]
            value = segment_csr(value, ptr, reduce=reduce)

        new_row = torch.cat([row, col], dim=0)[idx]
        new_col = torch.cat([col, row], dim=0)[idx]

        out = SparseTensor(
            row=new_row,
            rowptr=None,
            col=new_col,
            value=value,
            sparse_sizes=(N, N),
            is_sorted=True,
            trust_data=True,
        )
        return out

    def detach_(self):
        value = self.storage.value()
        if value is not None:
            value.detach_()
        return self

    def detach(self):
        value = self.storage.value()
        if value is not None:
            value = value.detach()
        return self.set_value(value, layout='coo')

    def requires_grad(self) -> bool:
        value = self.storage.value()
        if value is not None:
            return value.requires_grad
        else:
            return False

    def requires_grad_(
        self,
        requires_grad: bool = True,
        dtype: Optional[int] = None,
    ):
        if requires_grad and not self.has_value():
            self.fill_value_(1., dtype)

        value = self.storage.value()
        if value is not None:
            value.requires_grad_(requires_grad)
        return self

    def pin_memory(self):
        return self.from_storage(self.storage.pin_memory())

    def is_pinned(self) -> bool:
        return self.storage.is_pinned()

    def device(self):
        return self.storage.col().device

    def cpu(self):
        return self.to_device(device=torch.device('cpu'), non_blocking=False)

    def cuda(self):
        return self.from_storage(self.storage.cuda())

    def is_cuda(self) -> bool:
        return self.storage.col().is_cuda

    def dtype(self):
        value = self.storage.value()
        return value.dtype if value is not None else torch.float

    def is_floating_point(self) -> bool:
        value = self.storage.value()
        return torch.is_floating_point(value) if value is not None else True

    def bfloat16(self):
        return self.type(dtype=torch.bfloat16, non_blocking=False)

    def bool(self):
        return self.type(dtype=torch.bool, non_blocking=False)

    def byte(self):
        return self.type(dtype=torch.uint8, non_blocking=False)

    def char(self):
        return self.type(dtype=torch.int8, non_blocking=False)

    def half(self):
        return self.type(dtype=torch.half, non_blocking=False)

    def float(self):
        return self.type(dtype=torch.float, non_blocking=False)

    def double(self):
        return self.type(dtype=torch.double, non_blocking=False)

    def short(self):
        return self.type(dtype=torch.short, non_blocking=False)

    def int(self):
        return self.type(dtype=torch.int, non_blocking=False)

    def long(self):
        return self.type(dtype=torch.long, non_blocking=False)

    # Conversions #############################################################

    def to_dense(self, dtype: Optional[int] = None) -> torch.Tensor:
        row, col, value = self.coo()

        if value is not None:
            mat = torch.zeros(
                self.sizes(),
                dtype=value.dtype,
                device=self.device(),
            )
        else:
            mat = torch.zeros(self.sizes(), dtype=dtype, device=self.device())

        if value is not None:
            mat[row, col] = value
        else:
            mat[row, col] = torch.ones(
                self.nnz(),
                dtype=mat.dtype,
                device=mat.device,
            )

        return mat

    def to_torch_sparse_coo_tensor(
        self,
        dtype: Optional[int] = None,
    ) -> torch.Tensor:
        row, col, value = self.coo()
        index = torch.stack([row, col], dim=0)

        if value is None:
            value = torch.ones(self.nnz(), dtype=dtype, device=self.device())

        return torch.sparse_coo_tensor(index, value, self.sizes())

    def to_torch_sparse_csr_tensor(
        self,
        dtype: Optional[int] = None,
    ) -> torch.Tensor:
        rowptr, col, value = self.csr()

        if value is None:
            value = torch.ones(self.nnz(), dtype=dtype, device=self.device())

        return torch.sparse_csr_tensor(rowptr, col, value, self.sizes())

    def to_torch_sparse_csc_tensor(
        self,
        dtype: Optional[int] = None,
    ) -> torch.Tensor:
        colptr, row, value = self.csc()

        if value is None:
            value = torch.ones(self.nnz(), dtype=dtype, device=self.device())

        return torch.sparse_csc_tensor(colptr, row, value, self.sizes())


# Python Bindings #############################################################


def share_memory_(self: SparseTensor) -> SparseTensor:
    self.storage.share_memory_()
    return self


def is_shared(self: SparseTensor) -> bool:
    return self.storage.is_shared()


def to(self, *args: Optional[List[Any]],
       **kwargs: Optional[Dict[str, Any]]) -> SparseTensor:
    device, dtype, non_blocking = torch._C._nn._parse_to(*args, **kwargs)[:3]

    if dtype is not None:
        self = self.type(dtype=dtype, non_blocking=non_blocking)
    if device is not None:
        self = self.to_device(device=device, non_blocking=non_blocking)

    return self


def cpu(self) -> SparseTensor:
    return self.device_as(torch.tensor(0., device='cpu'))


def cuda(
    self,
    device: Optional[Union[int, str]] = None,
    non_blocking: bool = False,
):
    return self.device_as(torch.tensor(0., device=device or 'cuda'))


def __getitem__(self: SparseTensor, index: Any) -> SparseTensor:
    index = list(index) if isinstance(index, tuple) else [index]
    # More than one `Ellipsis` is not allowed...
    if len([
            i for i in index
            if not isinstance(i, (torch.Tensor, np.ndarray)) and i == ...
    ]) > 1:
        raise SyntaxError

    dim = 0
    out = self
    while len(index) > 0:
        item = index.pop(0)
        if isinstance(item, (list, tuple)):
            item = torch.tensor(item, device=self.device())
        if isinstance(item, np.ndarray):
            item = torch.from_numpy(item).to(self.device())

        if isinstance(item, int):
            out = out.select(dim, item)
            dim += 1
        elif isinstance(item, slice):
            if item.step is not None:
                raise ValueError('Step parameter not yet supported.')

            start = 0 if item.start is None else item.start
            start = self.size(dim) + start if start < 0 else start

            stop = self.size(dim) if item.stop is None else item.stop
            stop = self.size(dim) + stop if stop < 0 else stop

            out = out.narrow(dim, start, max(stop - start, 0))
            dim += 1
        elif torch.is_tensor(item):
            if item.dtype == torch.bool:
                out = out.masked_select(dim, item)
                dim += 1
            elif item.dtype == torch.long:
                out = out.index_select(dim, item)
                dim += 1
        elif item == Ellipsis:
            if self.dim() - len(index) < dim:
                raise SyntaxError
            dim = self.dim() - len(index)
        else:
            raise SyntaxError

    return out


def __repr__(self: SparseTensor) -> str:
    i = ' ' * 6
    row, col, value = self.coo()
    infos = []
    infos += [f'row={indent(row.__repr__(), i)[len(i):]}']
    infos += [f'col={indent(col.__repr__(), i)[len(i):]}']

    if value is not None:
        infos += [f'val={indent(value.__repr__(), i)[len(i):]}']

    infos += [
        f'size={tuple(self.sizes())}, nnz={self.nnz()}, '
        f'density={100 * self.density():.02f}%'
    ]

    infos = ',\n'.join(infos)

    i = ' ' * (len(self.__class__.__name__) + 1)
    return f'{self.__class__.__name__}({indent(infos, i)[len(i):]})'


SparseTensor.share_memory_ = share_memory_
SparseTensor.is_shared = is_shared
SparseTensor.to = to
SparseTensor.cpu = cpu
SparseTensor.cuda = cuda
SparseTensor.__getitem__ = __getitem__
SparseTensor.__repr__ = __repr__

# Scipy Conversions ###########################################################

ScipySparseMatrix = Union[scipy.sparse.coo_matrix, scipy.sparse.csr_matrix,
                          scipy.sparse.csc_matrix]


@torch.jit.ignore
def from_scipy(mat: ScipySparseMatrix, has_value: bool = True) -> SparseTensor:
    colptr = None
    if isinstance(mat, scipy.sparse.csc_matrix):
        colptr = torch.from_numpy(mat.indptr).to(torch.long)

    mat = mat.tocsr()
    rowptr = torch.from_numpy(mat.indptr).to(torch.long)
    mat = mat.tocoo()
    row = torch.from_numpy(mat.row).to(torch.long)
    col = torch.from_numpy(mat.col).to(torch.long)
    value = None
    if has_value:
        value = torch.from_numpy(mat.data)
    sparse_sizes = mat.shape[:2]

    storage = SparseStorage(
        row=row,
        rowptr=rowptr,
        col=col,
        value=value,
        sparse_sizes=sparse_sizes,
        rowcount=None,
        colptr=colptr,
        colcount=None,
        csr2csc=None,
        csc2csr=None,
        is_sorted=True,
    )

    return SparseTensor.from_storage(storage)


@torch.jit.ignore
def to_scipy(
    self: SparseTensor,
    layout: Optional[str] = None,
    dtype: Optional[torch.dtype] = None,
) -> ScipySparseMatrix:
    assert self.dim() == 2
    layout = get_layout(layout)

    if not self.has_value():
        ones = torch.ones(self.nnz(), dtype=dtype).numpy()

    if layout == 'coo':
        row, col, value = self.coo()
        row = row.detach().cpu().numpy()
        col = col.detach().cpu().numpy()
        value = value.detach().cpu().numpy() if self.has_value() else ones
        return scipy.sparse.coo_matrix((value, (row, col)), self.sizes())
    elif layout == 'csr':
        rowptr, col, value = self.csr()
        rowptr = rowptr.detach().cpu().numpy()
        col = col.detach().cpu().numpy()
        value = value.detach().cpu().numpy() if self.has_value() else ones
        return scipy.sparse.csr_matrix((value, col, rowptr), self.sizes())
    elif layout == 'csc':
        colptr, row, value = self.csc()
        colptr = colptr.detach().cpu().numpy()
        row = row.detach().cpu().numpy()
        value = value.detach().cpu().numpy() if self.has_value() else ones
        return scipy.sparse.csc_matrix((value, row, colptr), self.sizes())


SparseTensor.from_scipy = from_scipy
SparseTensor.to_scipy = to_scipy