View Source Nx.Defn (Nx v0.9.0)
Numerical functions.
A numerical function is a subset of Elixir tailored for numerical computations. For example, the following function:
defmodule MyModule do
import Nx.Defn
defn softmax(t) do
Nx.exp(t) / Nx.sum(Nx.exp(t))
end
end
will work with scalars, vector, matrices, and n-dimensional tensors. Depending on your compiler of choice, the code can even be JIT-compiled and run either on the CPU or GPU.
To support these features, defn
is a subset of Elixir. It
replaces Elixir's Kernel
by Nx.Defn.Kernel
. Nx.Defn.Kernel
provides tensor-aware operators, such as +
, -
, etc, while
also preserving many high-level constructs known to Elixir
developers, such as pipe operator, aliases, conditionals,
pattern-matching, the access syntax, and more:
For example, the code above can also be written as:
defmodule MyModule do
import Nx.Defn
defn softmax(t) do
t
|> Nx.exp()
|> then(& &1 / Nx.sum(&1))
end
end
Please consult Nx.Defn.Kernel
for a complete reference.
Some of the functions in this module may also be used within
defn
.
Operators
defn
attempts to keep as close to the Elixir semantics as
possible but that's not achievable. For example, mathematical
and bitwise operators (+
, -
, &&&
, <<<
, etc.) in Elixir
work on numbers, which means mapping them to tensors is
straight-forward and they largely preserve the same semantics,
except they are now multi-dimensional.
On the other hand, the logical operators and
, or
, and not
work with booleans in Elixir (true
and false
), which map
to 0
and 1
in defn
.
Therefore, when working with logical operators inside defn
,
0
is considered false
and all other numbers are considered
true
, which is represented as the number 1
. For example, in
defn
, 0 and 1
as well as 0 and 2
return 0
, while
1 and 1
or 1 and -1
will return 1
.
The same semantics apply to conditional expressions inside defn
,
such as if
, while
, etc.
JIT compilers
The power of Nx.Defn
is given by its compilers. The default
compiler is Nx.Defn.Evaluator
, which evalutes the code.
You can use jit/3
to compile a function on the fly using a
different compiler, such as EXLA
:
fun = Nx.Defn.jit(&MyModule.softmax/1, compiler: EXLA)
fun.(my_tensor)
The above will return an anonymous function that optimizes,
compiles, and run softmax
on the fly on the CPU (or the GPU)
if available. EXLA, in particular, also exports a EXLA.jit/2
function for convenience.
defn
functions are compiled when they are invoked, based on
the type and shapes of the tensors given as arguments.
Therefore compilation may be quite time consuming on the first
invocation. The compilation is then cached based on the tensors
shapes and types. Calling the same function with a tensor of
different values but same shape and type means no recompilation
is performed.
For those interested in writing custom compilers, see Nx.Defn.Compiler
.
Invoking custom Elixir code
Inside defn
you can only call other defn
functions and
the functions in the Nx
module. However, it is possible
to use transforms, defined with either deftransform
or
deftransformp
to invoke any Elixir code.
You can call code which was defined with deftransform
from another module:
defmodule MyRemoteModule do
import Nx.Defn
deftransform remote_elixir_code(value) do
IO.inspect(value)
end
end
defn add_and_mult(a, b, c) do
res = a * b + c
MyRemoteModule.remote_elixir_code(res)
end
You can also define and call a private transform defined through deftransformp
:
defn add_and_mult(a, b, c) do
res = a * b + c
custom_elixir_code(res)
end
deftransformp custom_elixir_code(value), do: IO.inspect(value)
The only difference between using deftransform
and deftransformp
is whether you want to expose and share the code with other modules,
just like def
and defp
.
Transforms are useful to manipulate tensor expressions or
Elixir data structures without the constraints of defn
.
Inputs and outputs types
Nx
and defn
expect the arguments to be numbers, tensors,
or one composite data type that implements Nx.LazyContainer
.
Tuples and maps implement Nx.LazyContainer
by default.
As previously described, defn
are cached based on the shape,
type, and names of the input tensors, but not their values.
defn
also accepts two special arguments: functions (or tuples
of functions) and lists (most commonly as keyword lists). Those
values are passed as is to numerical definitions and cached as
a whole. For this reason, you must never capture tensors in
functions or pass tensors in keyword lists.
When numbers are given as arguments, they are always immediately converted to tensors on invocation. If you want to keep numbers as is or if you want to pass any other value to numerical definitions, they must be given as keyword lists.
Default arguments
defn
functions support default arguments. They are typically used
as options. For example, imagine you want to create a function named
zeros, which returns a tensor of zeroes with a given type and shape.
It could be implemented like this:
defn zeros(opts \\ []) do
opts = keyword!(opts, type: {:f, 32}, shape: {})
Nx.broadcast(Nx.tensor(0, type: opts[:type]), opts[:shape])
end
The function above accepts opts
which are then validated and given
default values via the keyword!/2
function. Note that while it is
possible to access options via the Access
syntax, such as opts[:shape]
,
it is not possible to directly call functions in the Keyword
module
inside defn
. To freely manipulate any Elixir value inside defn
,
you have to use transforms, as described in the "Invoking custom Elixir
code" section.
Important! When it comes to JIT compilation, each different set of options (as well as anonymous functions) will lead to a different compilation of the numerical function.
Furthermore, if tensors are given through keyword lists, they won't be cached effectively. Tensors in
defn
are cached based on their shape and type, not their value, but this is not true if the tensor is given via a default argument or captured by an anonymous function. For this reason, it is extremely discouraged to pass tensors through anonymous functions and default arguments.
Working with maps and structs
While Nx
supports maps in defn
, you must be careful if your numerical
definitions are receiving maps and returning maps. For example, imagine
this code:
defn update_a(map) do
%{map | a: Nx.add(map.a, 1)}
end
The following code increments the value under the key :a
by 1. However, because the function receives the whole map and
returns the whole map, it means if the map has 120 keys, the
whole map will be copied to the CPU/GPU, and then brought back.
However, if you do this instead:
defn update_a(map) do
Nx.add(map.a, 1)
end
And then update the map on Elixir, outside of defn
:
%{map | a: update_a(map)}
Nx
will only send the parts of the map that matters.
Recursion and loops
Given numerical definition first build a representation of
your code, it is not possible to write recursive (nor tail
recursive) code inside defn
. Instead, one must use
Nx.Defn.Kernel.while/4
.
Summary
Functions
Compiles the given anonymous function with the given tensor shapes.
Wraps an anonymous function to return its underlying defn expression.
Invokes the anonymous function to return its underlying defn expression.
Gets the default options for the current process.
Sets the default options for defn
in the current process.
Defines a public numerical function.
Defines a private numerical function.
Can be used to define bodiless clauses for multi-clause transforms.
Defines a transform that executes the given fun
with arg
when building defn
expressions.
Private function version for deftransform/1
Private function version for deftransform/2
Sets the default options globally.
Receives an anonymous function and returns a new anonymous function that returns the gradient of the input function when invoked.
Computes the gradient of the given var
on fun
.
Wraps an anonymous function with just-in-time compilation.
Invokes the anonymous function with just-in-time compilation.
Starts streaming the given anonymous function with just-in-time compilation.
Returns a backend corresponding to the compiler options.
Receives an anonymous function and returns a new anonymous function that returns the value and gradient of the input function when invoked.
Computes the value and gradient of the given var
on fun
with an optional data transformation.
Functions
Compiles the given anonymous function with the given tensor shapes.
While jit/2
compiles a function just-in time based on the
input shapes, this function precompiles the given anonymous
function based on the input shapes. This can be beneficial for
large numerical definitions, where the cache mechanism in jit/2
may take milliseconds.
For example, take the following definition:
defn softmax(t), do: Nx.exp(t) / Nx.sum(Nx.exp(t))
You can jit and then apply it as:
fun = Nx.Defn.compile(&softmax/1, [Nx.template({3}, {:s, 32})], compiler: EXLA)
fun.(Nx.tensor([1, 2, 3]))
You can also pass a mixture of templates and options when compiling a function. In such cases, you must only pass the inputs when invoking the compiled function, as the options will already be embedded in its compiled value:
fun = Nx.Defn.compile(&Nx.sum/2, [Nx.template({2, 2}, {:s, 32}), [axes: [1]]])
fun.(Nx.iota({2, 2}))
If the input tensors do not match the shape of the tensors given on compilation, it will raise.
Options
:compiler
- the compiler for the JIT compilation:hooks
- a map of hooks to execute. SeeNx.Defn.Kernel.hook/3
Wraps an anonymous function to return its underlying defn expression.
Warning
This function must be invoked for debugging purposes only.
Options
:hooks
- a map of hooks to execute. SeeNx.Defn.Kernel.hook/3
Invokes the anonymous function to return its underlying defn expression.
Warning
This function must be invoked for debugging purposes only.
It accepts the same options as debug_expr/2
.
Gets the default options for the current process.
Sets the default options for defn
in the current process.
The options defined here apply to all future invocations of
defn
done by the current process. It also applies to calls
to the jit/3
and stream/3
functions in this module.
The default options are stored only in the process dictionary
and override any global options. This means if you start a
separate process, such as Task
, the default options must be
set on the new process too.
The function returns the values that were previously set as default options.
This function must be used only for scripting and testing.
Examples
iex> Nx.Defn.default_options(compiler: EXLA, client: :cuda)
iex> Nx.Defn.default_options()
[compiler: EXLA, client: :cuda]
Defines a public numerical function.
Defines a private numerical function.
Private numerical functions are always inlined by
their callers at compilation time. This happens to
all local function calls within defn
.
Can be used to define bodiless clauses for multi-clause transforms.
See also: deftransform/2
Examples
deftransform foo(bar, baz \ 1)
deftransform foo(bar, 1), do: bar
deftransform foo(bar, baz), do: bar + baz
Defines a transform that executes the given fun
with arg
when building defn
expressions.
Example
Take the following defn expression:
defn tanh_power(a, b) do
Nx.tanh(a) + Nx.pow(b, 2)
end
Let's see a trivial example, which is to use IO.inspect/1
to
print a tensor expression at definition time:
defn tanh_power(a, b) do
Nx.tanh(a) + Nx.pow(b, 2) |> my_inspect()
end
deftransformp my_inspect(expr), do: IO.inspect(expr)
Or:
defn tanh_power(a, b) do
res = Nx.tanh(a) + Nx.pow(b, 2)
my_inspect(res)
res
end
When invoked in both cases, it will print the expression being built
by defn
:
#Nx.Defn.Expr<
parameter a
parameter c
b = tanh [ a ] ()
d = pow [ c, 2 ] ()
e = add [ b, d ] ()
>
Although, for convenience, you might use print_expr/2
instead.
Private function version for deftransform/1
Private function version for deftransform/2
Sets the default options globally.
The options defined here apply to all future invocations of
defn
. It also applies to calls to the jit/3
and stream/3
functions in this module.
You must avoid calling this function at runtime and mostly for testing purposes. You may also set in your test environment using configuration:
config :nx, :default_defn_options, [compiler: EXLA, client: :cuda]
The function returns the values that were previously set as global default options.
Receives an anonymous function and returns a new anonymous function that returns the gradient of the input function when invoked.
Examples
iex> fun = Nx.Defn.grad(fn x -> Nx.sin(x) end)
iex> fun.(Nx.tensor(0))
#Nx.Tensor<
f32
1.0
>
Computes the gradient of the given var
on fun
.
The result of the grad
function must be a scalar tensor.
If a non-scalar tensor is given, it is assumed the additional
dimensions are batch dimensions.
Examples
defn tanh_grad(t) do
grad(t, &Nx.tanh/1)
end
To differentiate on multiple vars, pass a tuple as first argument:
defn tanh_power_grad(a, b) do
grad({a, b}, fn {a, b} -> Nx.tanh(a) + Nx.pow(b, 2) end)
end
var_or_vars
can be any Nx.Container
with one or multiple
tensors.
Wraps an anonymous function with just-in-time compilation.
Once invoked, the wrapped anonymous function will perform just in time compilation with the configured compiler. For example, take the following definition:
defn softmax(t), do: Nx.exp(t) / Nx.sum(Nx.exp(t))
You can jit and then apply it as:
fun = Nx.Defn.jit(&softmax/1, compiler: EXLA)
fun.(Nx.tensor([1, 2, 3]))
Options
:compiler
- the compiler for the JIT compilation:hooks
- a map of hooks to execute. SeeNx.Defn.Kernel.hook/3
:on_conflict
- what to do if a JIT compilation is already in place. It may be:raise
(the default),:force
(forces a new JIT compilation), or:reuse
(reuses the exiting JIT compilation). It is not recommended to set the:compiler
option when reusing.
Invokes the anonymous function with just-in-time compilation.
This function is equivalent to calling jit/2
and then applying
the given arguments to the anonymous function.
For example, take the following definition:
defn softmax(t), do: Nx.exp(t) / Nx.sum(Nx.exp(t))
You can jit_apply/3
it as:
Nx.Defn.jit_apply(&softmax/1, [Nx.tensor([1, 2, 3])], compiler: EXLA)
It accepts the same options as jit/2
.
Starts streaming the given anonymous function with just-in-time compilation.
At least two arguments are expected:
The first argument is a tensor template of the data to be streamed in
The second argument is a tensor with the stream initial state
The streaming function must return a two element tuple, the first element is the data to be sent and the second is the accumulator.
For each streamed chunk, you must call Nx.Stream.send/2
and
Nx.Stream.recv/1
. You don't need to call recv
immediately
after send
, but doing so can be a useful mechanism to provide
backpressure. Once all chunks are sent, you must use Nx.Stream.done/1
to receive the accumulated result. Let's see an example:
defmodule Streamed do
import Nx.Defn
defn sum(tensor, acc) do
{acc, tensor + acc}
end
end
Now let's invoke it:
stream = Nx.Defn.stream(&Streamed.sum/2, [Nx.template({}, {:s, 32}), 0])
for i <- 1..5 do
Nx.Stream.send(stream, i)
IO.inspect {:chunk, Nx.Stream.recv(stream)}
end
IO.inspect {:result, Nx.Stream.done(stream)}
It will print:
{:chunk, 0}
{:chunk, 1}
{:chunk, 2}
{:chunk, 3}
{:chunk, 4}
{:result, 5}
Options
:hooks
- a map of hooks to execute. SeeNx.Defn.Kernel.hook/3
Beware: deadlocks
Some backends (such as XLA) place locks around devices. For example, if you start streaming on the GPU, you cannot perform any other operation on the GPU until streaming is over.
This means if we modify the loop above to the following:
for i <- 1..5 do
Nx.Stream.send(stream, Nx.tensor(i) |> Nx.multiply(2))
IO.inspect {:chunk, Nx.Stream.recv(stream)}
end
The loop may deadlock at the time it performs the multiplication. In practice, this means you should perform the streaming on the GPU and the remaining operations on the CPU. If you only have a single device (i.e. only a CPU), then it may not be possible to perform the above and you will have to restructure your code to manipulate the input before streaming starts.
Returns a backend corresponding to the compiler options.
The backend matches the backend used for outputs from computations defined by the given compiler.
Receives an anonymous function and returns a new anonymous function that returns the value and gradient of the input function when invoked.
Examples
iex> fun = Nx.Defn.value_and_grad(fn x -> Nx.sin(x) end)
iex> {value, grad} = fun.(Nx.tensor(0))
iex> value
#Nx.Tensor<
f32
0.0
>
iex> grad
#Nx.Tensor<
f32
1.0
>
Computes the value and gradient of the given var
on fun
with an optional data transformation.
It returns a tuple with the value and the gradient.
Examples
defn tanh_grad(t) do
value_and_grad(t, &Nx.tanh/1)
end
To differentiate on multiple vars, pass a tuple as first argument:
defn tanh_power_grad(a, b) do
value_and_grad({a, b}, fn {a, b} -> Nx.tanh(a) + Nx.pow(b, 2) end)
end
var_or_vars
can be any Nx.Container
with one or multiple
tensors.
transform
allows you to transform the expression before the gradient is
calculated. This enables optimizations that reuse parts of expressions. As
an example, consider the following objective function:
defn objective(predict_fn, loss_fn, params, inputs, targets) do
preds = predict_fn.(params, inputs)
loss = loss_fn.(preds, targets)
{preds, loss}
end
You can compute the gradient with respect to just the loss function by applying a transform:
{{preds, loss}, gradient} = value_and_grad(params, &objective(predict_fn, loss_fn, &1, inputs, targets), &elem(&1, 1))
preds
can be re-used to compute other metrics such as accuracy, absolute error,
etc. without having to do another forward pass.