If at least one of `x`

or `y`

is a `tf.Tensor`

object, the expressions `tf.add(x, y)`

and `x + y`

are equivalent. The main reason you might use `tf.add()`

is to specify an explicit `name`

keyword argument for the created op, which is not possible with the overloaded operator version.

Note that if neither `x`

nor `y`

is a `tf.Tensor`

—for example if they are NumPy arrays—then `x + y`

will not create a TensorFlow op. `tf.add()`

always creates a TensorFlow op and converts its arguments to `tf.Tensor`

objects. Therefore, if you are writing a library function that might accept both tensors and NumPy arrays, you might prefer to use `tf.add()`

.

The following operators are overloaded in the TensorFlow Python API:

`__neg__`

(unary `-`

)
`__abs__`

(`abs()`

)
`__invert__`

(unary `~`

)
`__add__`

(binary `+`

)
`__sub__`

(binary `-`

)
`__mul__`

(binary elementwise `*`

)
`__div__`

(binary `/`

in Python 2)
`__floordiv__`

(binary `//`

in Python 3)
`__truediv__`

(binary `/`

in Python 3)
`__mod__`

(binary `%`

)
`__pow__`

(binary `**`

)
`__and__`

(binary `&`

)
`__or__`

(binary `|`

)
`__xor__`

(binary `^`

)
`__lt__`

(binary `<`

)
`__le__`

(binary `<=`

)
`__gt__`

(binary `>`

)
`__ge__`

(binary `>=`

)

Please note, `__eq__`

( binary `==`

) is **not** overloaded. `x == y`

will simply return a Python boolean whether `x`

and `y`

refer to the same tensor. You need to use `tf.equal()`

explicitly to check for element-wise equality. Same goes for not equal, `__ne__`

( binary `!=`

).