View Source Nx.Serving behaviour (Nx v0.6.0)
Serving encapsulates client and server work to perform batched requests.
Servings can be executed on the fly, without starting a server, but most often they are used to run servers that batch requests until a given size or timeout is reached.
More specifically, servings are a mechanism to apply a computation on a
Nx.Batch
, with hooks for preprocessing input from and postprocessing
output for the client. Thus we can think of an instance of Nx.Serving.t/0
(a serving) as something that encapsulates batches of Nx computations.
Inline/serverless workflow
First, let's define a simple numerical definition function:
defmodule MyDefn do
import Nx.Defn
defnp print_and_multiply(x) do
x = print_value(x, label: "debug")
x * 2
end
end
The function prints the given tensor and doubles its contents.
We can use new/1
to create a serving that will return a JIT
or AOT compiled function to execute on batches of tensors:
iex> serving = Nx.Serving.new(fn opts -> Nx.Defn.jit(&MyDefn.print_and_multiply/1, opts) end)
iex> batch = Nx.Batch.stack([Nx.tensor([1, 2, 3])])
iex> Nx.Serving.run(serving, batch)
debug: #Nx.Tensor<
s64[1][3]
[
[1, 2, 3]
]
>
#Nx.Tensor<
s64[1][3]
[
[2, 4, 6]
]
>
We started the serving by passing a function that receives
compiler options and returns a JIT or AOT compiled function.
We called Nx.Defn.jit/2
passing the options received as
argument, which will customize the JIT/AOT compilation.
You should see two values printed. The former is the result of
Nx.Defn.Kernel.print_value/1
, which shows the tensor that was
actually part of the computation and how it was batched.
The latter is the result of the computation.
When defining a Nx.Serving
, we can also customize how the data is
batched by using the client_preprocessing
as well as the result by
using client_postprocessing
hooks. Let's give it another try,
this time using jit/2
to create the serving, which automatically
wraps the given function in Nx.Defn.jit/2
for us:
iex> serving = (
...> Nx.Serving.jit(&MyDefn.print_and_multiply/1)
...> |> Nx.Serving.client_preprocessing(fn input -> {Nx.Batch.stack(input), :client_info} end)
...> |> Nx.Serving.client_postprocessing(&{&1, &2})
...> )
iex> Nx.Serving.run(serving, [Nx.tensor([1, 2]), Nx.tensor([3, 4])])
debug: #Nx.Tensor<
s64[2][2]
[
[1, 2],
[3, 4]
]
>
{{#Nx.Tensor<
s64[2][2]
[
[2, 4],
[6, 8]
]
>,
:server_info},
:client_info}
You can see the results are a bit different now. First of all, notice that
we were able to run the serving passing a list of tensors. Our custom
client_preprocessing
function stacks those tensors into a batch of two
entries and returns a tuple with a Nx.Batch
struct and additional client
information which we represent as the atom :client_info
. The default
client preprocessing simply enforces a batch was given and returns no client
information.
Then the result is a triplet tuple, returned by the client
postprocessing function, containing the result, the server information
(which we will later learn how to customize), and the client information.
From this, we can infer the default implementation of client_postprocessing
simply returns the result, discarding the server and client information.
So far, Nx.Serving
has not given us much. It has simply encapsulated the
execution of a function. Its full power comes when we start running our own
Nx.Serving
process. That's when we will also learn why we have a client_
prefix in some of the function names.
Stateful/process workflow
Nx.Serving
allows us to define an Elixir process to handle requests.
This process provides several features, such as batching up to a given
size or time, partitioning, and distribution over a group of nodes.
To do so, we need to start a Nx.Serving
process with a serving inside
a supervision tree:
children = [
{Nx.Serving,
serving: Nx.Serving.jit(&MyDefn.print_and_multiply/1),
name: MyServing,
batch_size: 10,
batch_timeout: 100}
]
Supervisor.start_child(children, strategy: :one_for_one)
Note: in your actual application, you want to make sure
Nx.Serving
comes early in your supervision tree, for example before your web application endpoint or your data processing pipelines, as those processes may end-up hitting Nx.Serving.
Now you can send batched runs to said process:
iex> batch = Nx.Batch.stack([Nx.tensor([1, 2, 3]), Nx.tensor([4, 5, 6])])
iex> Nx.Serving.batched_run(MyServing, batch)
debug: #Nx.Tensor<
s64[2][3]
[
[1, 2, 3],
[4, 5, 6]
]
>
#Nx.Tensor<
s64[2][3]
[
[2, 4, 6],
[8, 10, 12]
]
>
In the example, we pushed a batch of 2 and eventually got a reply. The process will wait for requests from other processes, for up to 100 milliseconds or until it gets 10 entries. Then it merges all batches together and once the result is computed, it slices and distributes those responses to each caller.
If there is any client_preprocessing
function, it will be executed
before the batch is sent to the server. If there is any client_postprocessing
function, it will be executed after getting the response from the
server.
Partitioning
You can start several partitions under the same serving by passing
partitions: true
when starting the serving. The number of partitions
will be determined according your compiler and for which host it is
compiling.
For example, when creating the serving, you may pass the following
defn_options
:
Nx.Serving.new(computation, compiler: EXLA, client: :cuda)
Now when booting up the serving:
children = [
{Nx.Serving,
serving: serving,
name: MyServing,
batch_size: 10,
batch_timeout: 100,
partitions: true}
]
If you have two GPUs, batched_run/3
will now gather batches and send
them to the GPUs as they become available to process requests.
Distribution
All Nx.Serving
s are distributed by default. If the current machine
does not have an instance of Nx.Serving
running, batched_run/3
will
automatically look for one in the cluster. The nodes do not need to run
the same code and applications. It is only required that they run the
same Nx
version.
The load balancing between servings is done randomly, however, the number
of partitions are considered if the partitions: true
option is also given.
For example, if you have a node with 2 GPUs and another with 4, the latter
will receive the double of requests compared to the former.
batched_run/3
receives an optional distributed_preprocessing
callback as
third argument for preprocessing the input for distributed requests. When
using libraries like EXLA or Torchx, the tensor is often allocated in memory
inside a third-party library so it is necessary to either transfer or copy
the tensor to the binary backend before sending it to another node.
This can be done by passing either Nx.backend_transfer/1
or Nx.backend_copy/1
as third argument:
Nx.Serving.batched_run(MyDistributedServing, input, &Nx.backend_copy/1)
Use backend_transfer/1
if you know the input will no longer be used.
Similarly, the serving has a distributed_postprocessing
callback which can do
equivalent before sending the reply to the caller.
The servings are dispatched using Erlang Distribution. You can use
Node.connect/1
to manually connect nodes. In a production setup, this is
often done with the help of libraries like libcluster
.
Advanced notes
Module-based serving
In the examples so far, we have been using the default version of
Nx.Serving
, which executes the given function for each batch.
However, we can also use new/2
to start a module-based version of
Nx.Serving
which gives us more control over both inline and process
workflows. A simple module implementation of a Nx.Serving
could look
like this:
defmodule MyServing do
@behaviour Nx.Serving
defnp print_and_multiply(x) do
x = print_value({:debug, x})
x * 2
end
@impl true
def init(_inline_or_process, :unused_arg, [defn_options]) do
{:ok, Nx.Defn.jit(&print_and_multiply/1, defn_options)}
end
@impl true
def handle_batch(batch, 0, function) do
{:execute, fn -> {function.(batch), :server_info} end, function}
end
end
It has two functions. The first, init/3
, receives the type of serving
(:inline
or :process
) and the serving argument. In this step,
we capture print_and_multiply/1
as a jitted function.
The second function is called handle_batch/3
. This function
receives a Nx.Batch
and returns a function to execute.
The function itself must return a two element-tuple: the batched
results and some server information. The server information can
be any value and we set it to the atom :server_info
.
Now let's give it a try by defining a serving with our module and then running it on a batch:
iex> serving = Nx.Serving.new(MyServing, :unused_arg)
iex> batch = Nx.Batch.stack([Nx.tensor([1, 2, 3])])
iex> Nx.Serving.run(serving, batch)
{:debug, #Nx.Tensor<
s64[1][3]
[
[1, 2, 3]
]
>}
#Nx.Tensor<
s64[1][3]
[
[2, 4, 6]
]
>
From here on, you use start_link/1
to start this serving in your
supervision and even customize client_preprocessing/1
and
client_postprocessing/1
callbacks to this serving, as seen in the
previous sections.
Note in our implementation above assumes it won't run partitioned.
In partitioned mode, init/3
may receive multiple defn_options
as the third argument and handle_batch/3
may receive another partition
besides 0.
Batch keys
Sometimes it may be necessary to execute different functions under the same serving. For example, sequence transformers must pad the sequence to a given length. However, if you are batching, the length must be padded upfront. If the length is too small, you have to either discard data or support only small inputs. If the length is too large, then you decrease performance with the extra padding.
Batch keys provide a mechanism to accumulate different batches, based on their key, which execute independently. As an example, we will do a serving which performs different operations based on the batch key, but it could also be used to perform the same operation for different templates:
iex> args = [Nx.template({10}, :s64)]
iex> serving = Nx.Serving.new(fn
...> :double, opts -> Nx.Defn.compile(&Nx.multiply(&1, 2), args, opts)
...> :half, opts -> Nx.Defn.compile(&Nx.divide(&1, 2), args, opts)
...> end)
iex> double_batch = Nx.Batch.concatenate([Nx.iota({10})]) |> Nx.Batch.key(:double)
iex> Nx.Serving.run(serving, double_batch)
#Nx.Tensor<
s64[10]
[0, 2, 4, 6, 8, 10, 12, 14, 16, 18]
>
iex> half_batch = Nx.Batch.concatenate([Nx.iota({10})]) |> Nx.Batch.key(:half)
iex> Nx.Serving.run(serving, half_batch)
#Nx.Tensor<
f32[10]
[0.0, 0.5, 1.0, 1.5, 2.0, 2.5, 3.0, 3.5, 4.0, 4.5]
>
When using a process-based serving, you must specify the supported
:batch_keys
when the process is started. The batch keys will be
available inside the defn_options
passed as the third argument of
the init/3
callback. The batch keys will also be verified
when the batch is returned from the client-preprocessing callback.
Summary
Callbacks
Receives a batch, a partition, and returns a function to execute the batch.
The callback used to initialize the serving.
Functions
Runs the given input
on the serving process given by name
.
Sets the client postprocessing function.
Sets the client preprocessing function.
Sets the defn options of this serving.
Sets the distributed postprocessing function.
Creates a new serving by jitting the given fun
with defn_options
.
Creates a new function serving.
Creates a new module-based serving.
Sets the process options of this serving.
Runs serving
with the given input
inline with the current process.
Starts a Nx.Serving
process to batch requests to a given serving.
Marks this serving as a streaming serving.
Types
@type client_info() :: term()
@type client_postprocessing() :: ({Nx.Container.t(), metadata()}, client_info() -> term())
@type client_preprocessing() :: (term() -> {Nx.Batch.t(), client_info()})
@type metadata() :: term()
@type t() :: %Nx.Serving{ arg: term(), client_postprocessing: client_postprocessing(), client_preprocessing: client_preprocessing(), defn_options: keyword(), distributed_postprocessing: distributed_postprocessing(), module: atom(), process_options: keyword(), streaming: nil | %{hooks: [atom()]} }
Callbacks
@callback handle_batch(Nx.Batch.t(), partition :: non_neg_integer(), state) :: {:execute, (-> {Nx.Container.t(), metadata()}), state} when state: term()
Receives a batch, a partition, and returns a function to execute the batch.
In case of serving processes, the function is executed is an separate process.
@callback init(type :: :inline | :process, arg :: term(), [defn_options :: keyword()]) :: {:ok, state :: term()}
The callback used to initialize the serving.
The first argument reveals if the serving is executed inline,
such as by calling run/2
, by started with the process.
The second argument is the serving argument given to new/2
.
The third argument option is a list of compiler options to be
used to compile each partition the serving will run.
It must return {:ok, state}
, where the state
can be any term.
Functions
batched_run(name, input, distributed_preprocessing \\ &Function.identity/1)
View SourceRuns the given input
on the serving process given by name
.
name
is either an atom representing a local or distributed
serving process. First it will attempt to dispatch locally, then it
falls back to the distributed serving. You may specify
{:local, name}
to force a local lookup or {:distributed, name}
to force a distributed one.
The client_preprocessing
callback will be invoked on the input
which is then sent to the server. The server will batch requests
and send a response either when the batch is full or on timeout.
Then client_postprocessing
is invoked on the response. See the
module documentation for more information. In the distributed case,
the callbacks are invoked in the distributed node, but still outside of
the serving process.
Note that you cannot batch an input
larger than the configured
:batch_size
in the server.
Distributed mode
To run in distributed mode, the nodes do not need to run the same
code and applications. It is only required that they run the
same Nx
version.
If the current node is running a serving given by name
locally
and {:distributed, name}
is used, the request will use the same
distribution mechanisms instead of being handled locally, which
is useful for testing locally without a need to spawn nodes.
This function receives an optional distributed_preprocessing
callback as
third argument for preprocessing the input for distributed requests. When
using libraries like EXLA or Torchx, the tensor is often allocated in memory
inside a third-party library so it may be necessary to either transfer or copy
the tensor to the binary backend before sending it to another node.
This can be done by passing either Nx.backend_transfer/1
or Nx.backend_copy/1
as third argument:
Nx.Serving.batched_run(MyDistributedServing, input, &Nx.backend_copy/1)
Use backend_transfer/1
if you know the input will no longer be used.
Similarly, the serving has a distributed_postprocessing
callback which can do
equivalent before sending the reply to the caller.
Sets the client postprocessing function.
The client postprocessing receives a tuple with the
{output, metadata}
or a stream as first argument.
The second argument is always the additional information
returned by the client preprocessing.
The default implementation returns either the output or the stream.
Sets the client preprocessing function.
The default implementation creates a single element batch
with the given argument and is equivalent to &Nx.Batch.stack([&1])
.
Sets the defn options of this serving.
These are the options supported by Nx.Defn.default_options/1
.
Sets the distributed postprocessing function.
The default implementation is Function.identity/1
.
Creates a new serving by jitting the given fun
with defn_options
.
This is equivalent to:
new(fn opts -> Nx.Defn.jit(fun, opts) end, defn_options)
Creates a new function serving.
It expects a single- or double-arity function. If a single-arity
function is given, it receives the compiler options and must
return a JIT (via Nx.Defn.jit/2
) or AOT compiled (via
Nx.Defn.compile/3
) one-arity function.
If a double-arity function is given, it receives the batch
key as first argument and the compiler options as second argument.
It must return a JIT (via Nx.Defn.jit/2
) or AOT compiled
(via Nx.Defn.compile/3
) one-arity function, but in practice
it will be a Nx.Defn.compile/3
, since the purpose of the
batch key is often to precompile different versions of the
same function upfront. The batch keys can be given on
start_link/1
.
The function will be called with the arguments returned by the
client_preprocessing
callback.
Creates a new module-based serving.
It expects a module and an argument that is given to its init
callback.
A third optional argument called defn_options
are additional
compiler options which will be given to the module. Those options
will be merged into Nx.Defn.default_options/0
.
Sets the process options of this serving.
These are the same options as supported on start_link/1
,
except :name
and :serving
itself.
Runs serving
with the given input
inline with the current process.
Starts a Nx.Serving
process to batch requests to a given serving.
Options
:name
- an atom with the name of the process:serving
- aNx.Serving
struct with the serving configuration:batch_keys
- all available batch keys. Batch keys allows Nx.Serving to accumulate different batches with different properties. Defaults to[:default]
:batch_size
- the maximum batch size. A value is first read from theNx.Serving
struct and then it falls back to this option (which defaults to1
):batch_timeout
- the maximum time to wait, in milliseconds, before executing the batch. A value is first read from theNx.Serving
struct and then it falls back to this option (which defaults to100
ms):partitions
- whentrue
, starts several partitions under this serving. The number of partitions will be determined according to your compiler and for which host it is compiling. See the module docs for more information:shutdown
- the maximum time for the serving to shutdown. This will block until the existing computation finishes (defaults to30_000
ms):hibernate_after
and:spawn_opt
- configure the underlying serving workers (seeGenServer.start_link/3
)
Marks this serving as a streaming serving.
Once run/2
or batched_run/2
are invoked, it will then
return a stream. The stream is must be consumed in the same
process that calls run/2
or batched_run/2
.
Options
:hooks
- a list of hook names that will become streaming events
Implementation details
Client postprocessing
Once streaming is enabled, the client postprocessing callback will receive a stream which will emit events for each hook in the shape of:
{hook_name, term()}
Once the stream is done, it will emit {:done, output, metadata}
.
The client postprocessing is often expected to call
Stream.transform/3
to process those events into something usable
by callers.
Batch breaking
Another consequence of streaming is that a serving server can
no longer break a batch. For example, imagine you have a
batch_size
of 3 and you push three batches of two elements
(AA, BB, and CC). Without streaming, the batches will be consumed as:
AAB -> BCC
With streaming, we can't break the batch BB
, as above, so we will
consistently pad with zeroes:
AA0 -> BB0 -> CC0
In practice, this should not be a major problem, as you should generally avoid having a batch size that is not a multiple of the most common batches.