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# tfp.substrates.numpy.bijectors.Exp

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Compute `Y = g(X) = exp(X)`.

#### Example Use:

``````# Create the Y=g(X)=exp(X) transform which works only on Tensors with 1
# batch ndim 2.
exp = Exp()
x = [[[1., 2],
[3, 4]],
[[5, 6],
[7, 8]]]
exp(x) == exp.forward(x)
log(x) == exp.inverse(x)
``````

`validate_args` Python `bool` indicating whether arguments should be checked for correctness.
`name` Python `str` name given to ops managed by this object.

`dtype`

`forward_min_event_ndims` Returns the minimal number of dimensions bijector.forward operates on.

Multipart bijectors return structured `ndims`, which indicates the expected structure of their inputs. Some multipart bijectors, notably Composites, may return structures of `None`.

`graph_parents` Returns this `Bijector`'s graph_parents as a Python list.
`has_static_min_event_ndims` Returns True if the bijector has statically-known `min_event_ndims`.
`inverse_min_event_ndims` Returns the minimal number of dimensions bijector.inverse operates on.

Multipart bijectors return structured `event_ndims`, which indicates the expected structure of their outputs. Some multipart bijectors, notably Composites, may return structures of `None`.

`is_constant_jacobian` Returns true iff the Jacobian matrix is not a function of x.

`name` Returns the string name of this `Bijector`.
`parameters` Dictionary of parameters used to instantiate this `Bijector`.
`power` The `c` in: `Y = g(X) = (1 + X * c)**(1 / c)`.
`trainable_variables`

`validate_args` Returns True if Tensor arguments will be validated.
`variables`

## Methods

### `copy`

View source

Creates a copy of the bijector.

Args
`**override_parameters_kwargs` String/value dictionary of initialization arguments to override with new values.

Returns
`bijector` A new instance of `type(self)` initialized from the union of self.parameters and override_parameters_kwargs, i.e., `dict(self.parameters, **override_parameters_kwargs)`.

### `experimental_batch_shape`

View source

Returns the batch shape of this bijector for inputs of the given rank.

The batch shape of a bijector decribes the set of distinct transformations it represents on events of a given size. For example: the bijector `tfb.Scale([1., 2.])` has batch shape `[2]` for scalar events (`event_ndims = 0`), because applying it to a scalar event produces two scalar outputs, the result of two different scaling transformations. The same bijector has batch shape `[]` for vector events, because applying it to a vector produces (via elementwise multiplication) a single vector output.

Bijectors that operate independently on multiple state parts, such as `tfb.JointMap`, must broadcast to a coherent batch shape. Some events may not be valid: for example, the bijector `tfd.JointMap([tfb.Scale([1., 2.]), tfb.Scale([1., 2., 3.])])` does not produce a valid batch shape when `event_ndims = [0, 0]`, since the batch shapes of the two parts are inconsistent. The same bijector does define valid batch shapes of `[]`, `[2]`, and `[3]` if `event_ndims` is `[1, 1]`, `[0, 1]`, or `[1, 0]`, respectively.

Since transforming a single event produces a scalar log-det-Jacobian, the batch shape of a bijector with non-constant Jacobian is expected to equal the shape of `forward_log_det_jacobian(x, event_ndims=x_event_ndims)` or `inverse_log_det_jacobian(y, event_ndims=y_event_ndims)`, for `x` or `y` of the specified `ndims`.

Args
`x_event_ndims` Optional Python `int` (structure) number of dimensions in a probabilistic event passed to `forward`; this must be greater than or equal to `self.forward_min_event_ndims`. If `None`, defaults to `self.forward_min_event_ndims`. Mutually exclusive with `y_event_ndims`. Default value: `None`.
`y_event_ndims` Optional Python `int` (structure) number of dimensions in a probabilistic event passed to `inverse`; this must be greater than or equal to `self.inverse_min_event_ndims`. Mutually exclusive with `x_event_ndims`. Default value: `None`.

Returns
`batch_shape` `TensorShape` batch shape of this bijector for a value with the given event rank. May be unknown or partially defined.

### `experimental_batch_shape_tensor`

View source

Returns the batch shape of this bijector for inputs of the given rank.

The batch shape of a bijector decribes the set of distinct transformations it represents on events of a given size. For example: the bijector `tfb.Scale([1., 2.])` has batch shape `[2]` for scalar events (`event_ndims = 0`), because applying it to a scalar event produces two scalar outputs, the result of two different scaling transformations. The same bijector has batch shape `[]` for vector events, because applying it to a vector produces (via elementwise multiplication) a single vector output.

Bijectors that operate independently on multiple state parts, such as `tfb.JointMap`, must broadcast to a coherent batch shape. Some events may not be valid: for example, the bijector `tfd.JointMap([tfb.Scale([1., 2.]), tfb.Scale([1., 2., 3.])])` does not produce a valid batch shape when `event_ndims = [0, 0]`, since the batch shapes of the two parts are inconsistent. The same bijector does define valid batch shapes of `[]`, `[2]`, and `[3]` if `event_ndims` is `[1, 1]`, `[0, 1]`, or `[1, 0]`, respectively.

Since transforming a single event produces a scalar log-det-Jacobian, the batch shape of a bijector with non-constant Jacobian is expected to equal the shape of `forward_log_det_jacobian(x, event_ndims=x_event_ndims)` or `inverse_log_det_jacobian(y, event_ndims=y_event_ndims)`, for `x` or `y` of the specified `ndims`.

Args
`x_event_ndims` Optional Python `int` (structure) number of dimensions in a probabilistic event passed to `forward`; this must be greater than or equal to `self.forward_min_event_ndims`. If `None`, defaults to `self.forward_min_event_ndims`. Mutually exclusive with `y_event_ndims`. Default value: `None`.
`y_event_ndims` Optional Python `int` (structure) number of dimensions in a probabilistic event passed to `inverse`; this must be greater than or equal to `self.inverse_min_event_ndims`. Mutually exclusive with `x_event_ndims`. Default value: `None`.

Returns
`batch_shape_tensor` integer `Tensor` batch shape of this bijector for a value with the given event rank.

### `experimental_compute_density_correction`

View source

Density correction for this transformation wrt the tangent space, at x.

Subclasses of Bijector may call the most specific applicable method of `TangentSpace`, based on whether the transformation is dimension-preserving, coordinate-wise, a projection, or something more general. The backward-compatible assumption is that the transformation is dimension-preserving (goes from R^n to R^n).

Args
`x` `Tensor` (structure). The point at which to calculate the density.
`tangent_space` `TangentSpace` or one of its subclasses. The tangent to the support manifold at `x`.
`backward_compat` `bool` specifying whether to assume that the Bijector is dimension-preserving.
`**kwargs` Optional keyword arguments forwarded to tangent space methods.

Returns
`density_correction` `Tensor` representing the density correction---in log space---under the transformation that this Bijector denotes.

Raises
TypeError if `backward_compat` is False but no method of `TangentSpace` has been called explicitly.

### `forward`

View source

Returns the forward `Bijector` evaluation, i.e., X = g(Y).

Args
`x` `Tensor` (structure). The input to the 'forward' evaluation.
`name` The name to give this op.
`**kwargs` Named arguments forwarded to subclass implementation.

Returns
`Tensor` (structure).

Raises
`TypeError` if `self.dtype` is specified and `x.dtype` is not `self.dtype`.
`NotImplementedError` if `_forward` is not implemented.

### `forward_dtype`

View source

Returns the dtype returned by `forward` for the provided input.