# Generated content DO NOT EDIT from typing import Any, Callable, Dict, List, Optional, Tuple, Union, Sequence from os import PathLike from candle.typing import _ArrayLike, Device, Scalar, Index class bf16(DType): pass @staticmethod def cat(tensors: List[Tensor], dim: int) -> Tensor: """ Concatenate the tensors across one axis. """ pass class f16(DType): pass class f32(DType): pass class f64(DType): pass class i64(DType): pass @staticmethod def ones(shape: Sequence[int], dtype: Optional[DType] = None, device: Optional[Device] = None) -> Tensor: """ Creates a new tensor filled with ones. """ pass @staticmethod def rand(shape: Sequence[int], device: Optional[Device] = None) -> Tensor: """ Creates a new tensor with random values. """ pass @staticmethod def randn(shape: Sequence[int], device: Optional[Device] = None) -> Tensor: """ Creates a new tensor with random values from a normal distribution. """ pass @staticmethod def stack(tensors: List[Tensor], dim: int) -> Tensor: """ Stack the tensors along a new axis. """ pass @staticmethod def tensor(data: _ArrayLike) -> Tensor: """ Creates a new tensor from a Python value. The value can be a scalar or array-like object. """ pass class u32(DType): pass class u8(DType): pass @staticmethod def zeros(shape: Sequence[int], dtype: Optional[DType] = None, device: Optional[Device] = None) -> Tensor: """ Creates a new tensor filled with zeros. """ pass class DType: """ A `candle` dtype. """ class QTensor: """ A quantized tensor. """ def dequantize(self) -> Tensor: """ Dequantizes the tensor. """ pass @property def ggml_dtype(self) -> str: """ Gets the tensors quantized dtype. """ pass def matmul_t(self, lhs: Tensor) -> Tensor: """ Performs a quantized matrix multiplication, with the quantized tensor as the right hand side. """ pass @property def rank(self) -> int: """ Gets the rank of the tensor. """ pass @property def shape(self) -> Tuple[int]: """ Gets the shape of the tensor. """ pass class Tensor: """ A `candle` tensor. """ def __init__(self, data: _ArrayLike): pass def __add__(self, rhs: Union[Tensor, Scalar]) -> "Tensor": """ Add a scalar to a tensor or two tensors together. """ pass def __getitem__(self, index: Union[Index, Tensor, Sequence[Index]]) -> "Tensor": """ Return a slice of a tensor. """ pass def __mul__(self, rhs: Union[Tensor, Scalar]) -> "Tensor": """ Multiply a tensor by a scalar or one tensor by another. """ pass def __radd__(self, rhs: Union[Tensor, Scalar]) -> "Tensor": """ Add a scalar to a tensor or two tensors together. """ pass def __richcmp__(self, rhs: Union[Tensor, Scalar], op) -> "Tensor": """ Compare a tensor with a scalar or one tensor with another. """ pass def __rmul__(self, rhs: Union[Tensor, Scalar]) -> "Tensor": """ Multiply a tensor by a scalar or one tensor by another. """ pass def __sub__(self, rhs: Union[Tensor, Scalar]) -> "Tensor": """ Subtract a scalar from a tensor or one tensor from another. """ pass def __truediv__(self, rhs: Union[Tensor, Scalar]) -> "Tensor": """ Divide a tensor by a scalar or one tensor by another. """ pass def argmax_keepdim(self, dim: int) -> Tensor: """ Returns the indices of the maximum value(s) across the selected dimension. """ pass def argmin_keepdim(self, dim: int) -> Tensor: """ Returns the indices of the minimum value(s) across the selected dimension. """ pass def broadcast_add(self, rhs: Tensor) -> Tensor: """ Adds the two tensors, while broadcasting the right-hand-side tensor to match the shape of the left-hand-side tensor. """ pass def broadcast_as(self, shape: Sequence[int]) -> Tensor: """ Broadcasts the tensor to the given shape. """ pass def broadcast_div(self, rhs: Tensor) -> Tensor: """ Divides the two tensors, while broadcasting the right-hand-side tensor to match the shape of the left-hand-side tensor. """ pass def broadcast_left(self, shape: Sequence[int]) -> Tensor: """ Broadcasts the tensor to the given shape, adding new dimensions on the left. """ pass def broadcast_mul(self, rhs: Tensor) -> Tensor: """ Multiplies the two tensors, while broadcasting the right-hand-side tensor to match the shape of the left-hand-side tensor. """ pass def broadcast_sub(self, rhs: Tensor) -> Tensor: """ Subtracts the two tensors, while broadcasting the right-hand-side tensor to match the shape of the left-hand-side tensor. """ pass def contiguous(self) -> Tensor: """ Makes the tensor contiguous in memory. """ pass def copy(self) -> Tensor: """ Returns a copy of the tensor. """ pass def cos(self) -> Tensor: """ Performs the `cos` operation on the tensor. """ pass def detach(self) -> Tensor: """ Detach the tensor from the computation graph. """ pass @property def device(self) -> Device: """ Gets the tensor's device. """ pass @property def dtype(self) -> DType: """ Gets the tensor's dtype. """ pass def exp(self) -> Tensor: """ Performs the `exp` operation on the tensor. """ pass def flatten_all(self) -> Tensor: """ Flattens the tensor into a 1D tensor. """ pass def flatten_from(self, dim: int) -> Tensor: """ Flattens the tensor on the dimension indexes from `dim` (inclusive) to the last dimension. """ pass def flatten_to(self, dim: int) -> Tensor: """ Flattens the tensor on the dimension indexes from `0` to `dim` (inclusive). """ pass def get(self, index: int) -> Tensor: """ Gets the value at the specified index. """ pass def index_select(self, rhs: Tensor, dim: int) -> Tensor: """ Select values for the input tensor at the target indexes across the specified dimension. The `indexes` is argument is an int tensor with a single dimension. The output has the same number of dimension as the `self` input. The target dimension of the output has length the length of `indexes` and the values are taken from `self` using the index from `indexes`. Other dimensions have the same number of elements as the input tensor. """ pass def is_contiguous(self) -> bool: """ Returns true if the tensor is contiguous in C order. """ pass def is_fortran_contiguous(self) -> bool: """ Returns true if the tensor is contiguous in Fortran order. """ pass def log(self) -> Tensor: """ Performs the `log` operation on the tensor. """ pass def matmul(self, rhs: Tensor) -> Tensor: """ Performs a matrix multiplication between the two tensors. """ pass def max_keepdim(self, dim: int) -> Tensor: """ Gathers the maximum value across the selected dimension. """ pass def mean_all(self) -> Tensor: """ Returns the mean of the tensor. """ pass def min_keepdim(self, dim: int) -> Tensor: """ Gathers the minimum value across the selected dimension. """ pass def narrow(self, dim: int, start: int, len: int) -> Tensor: """ Returns a new tensor that is a narrowed version of the input, the dimension `dim` ranges from `start` to `start + len`. """ pass def powf(self, p: float) -> Tensor: """ Performs the `pow` operation on the tensor with the given exponent. """ pass def quantize(self, quantized_dtype: str) -> QTensor: """ Quantize the tensor. """ pass @property def rank(self) -> int: """ Gets the tensor's rank. """ pass def recip(self) -> Tensor: """ Get the `recip` of the tensor. """ pass def reshape(self, shape: Sequence[int]) -> Tensor: """ Reshapes the tensor to the given shape. """ pass @property def shape(self) -> Tuple[int]: """ Gets the tensor's shape. """ pass def sin(self) -> Tensor: """ Performs the `sin` operation on the tensor. """ pass def sqr(self) -> Tensor: """ Squares the tensor. """ pass def sqrt(self) -> Tensor: """ Calculates the square root of the tensor. """ pass def squeeze(self, dim: int) -> Tensor: """ Creates a new tensor with the specified dimension removed if its size was one. """ pass @property def stride(self) -> Tuple[int]: """ Gets the tensor's strides. """ pass def sum_all(self) -> Tensor: """ Returns the sum of the tensor. """ pass def sum_keepdim(self, dim: Union[int, List[int]]) -> Tensor: """ Returns the sum of all elements in the input tensor. The sum is performed over all the input dimensions. """ pass def t(self) -> Tensor: """ Transposes the tensor. """ pass def to(self, *args, **kwargs) -> Tensor: """ Performs Tensor dtype and/or device conversion. """ pass def to_device(self, device: Union[str, Device]) -> Tensor: """ Move the tensor to a new device. """ pass def to_dtype(self, dtype: Union[str, DType]) -> Tensor: """ Convert the tensor to a new dtype. """ pass def to_torch(self) -> torch.Tensor: """ Converts candle's tensor to pytorch's tensor """ pass def transpose(self, dim1: int, dim2: int) -> Tensor: """ Returns a tensor that is a transposed version of the input, the given dimensions are swapped. """ pass def unsqueeze(self, dim: int) -> Tensor: """ Creates a new tensor with a dimension of size one inserted at the specified position. """ pass def values(self) -> _ArrayLike: """ Gets the tensor's data as a Python scalar or array-like object. """ pass def where_cond(self, on_true: Tensor, on_false: Tensor) -> Tensor: """ Returns a tensor with the same shape as the input tensor, the values are taken from `on_true` if the input tensor value is not zero, and `on_false` at the positions where the input tensor is equal to zero. """ pass