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batcher.cc
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// Copyright 2018 Google LLC
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// https://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
// TensorFlow operations for dynamic batching.
#include <deque>
#include <string>
#include <utility>
#include <vector>
#include "tensorflow/core/framework/op.h"
#include "tensorflow/core/framework/op_kernel.h"
#include "tensorflow/core/framework/resource_op_kernel.h"
#include "tensorflow/core/framework/shape_inference.h"
#include "tensorflow/core/lib/gtl/flatmap.h"
#include "tensorflow/core/lib/gtl/optional.h"
#include "tensorflow/core/lib/strings/strcat.h"
#include "tensorflow/core/util/batch_util.h"
#include "tensorflow/core/util/work_sharder.h"
namespace tensorflow {
namespace {
REGISTER_OP("Batcher")
.Output("handle: resource")
.Attr("minimum_batch_size: int")
.Attr("maximum_batch_size: int")
.Attr("timeout_ms: int")
.Attr("container: string = ''")
.Attr("shared_name: string = ''")
.SetIsStateful()
.SetShapeFn(shape_inference::ScalarShape)
.Doc(R"doc(
A Batcher which batches up computations into the same batch.
)doc");
REGISTER_OP("BatcherCompute")
.Input("handle: resource")
.Input("input_list: Tinput_list")
.Attr("Tinput_list: list(type) >= 1")
.Attr("Toutput_list: list(type) >= 1")
.Output("output_list: Toutput_list")
.SetShapeFn(shape_inference::UnknownShape)
.Doc(R"doc(
Puts the input into the computation queue, waits and returns the result.
)doc");
REGISTER_OP("BatcherGetInputs")
.Input("handle: resource")
.Attr("Toutput_list: list(type) >= 1")
.Output("output_list: Toutput_list")
.Output("computation_id: int64")
.SetShapeFn([](shape_inference::InferenceContext* c) {
for (int i = 0; i < c->num_outputs() - 1; ++i) {
c->set_output(i, c->UnknownShape());
}
return c->set_output("computation_id", {c->Scalar()});
})
.Doc(R"doc(
Gets a batch of inputs to compute the results of.
)doc");
REGISTER_OP("BatcherSetOutputs")
.Input("handle: resource")
.Input("input_list: Tinput_list")
.Input("computation_id: int64")
.Attr("Tinput_list: list(type) >= 1")
.SetShapeFn(shape_inference::UnknownShape)
.Doc(R"doc(
Sets the outputs of a batch for the function.
)doc");
REGISTER_OP("BatcherClose")
.Input("handle: resource")
.SetShapeFn(shape_inference::NoOutputs)
.Doc(R"doc(
Closes the batcher and cancels all pending batcher operations.
)doc");
class Batcher : public ResourceBase {
public:
using DoneCallback = AsyncOpKernel::DoneCallback;
Batcher(int32 minimum_batch_size, int32 maximum_batch_size,
gtl::optional<std::chrono::milliseconds> timeout)
: ResourceBase(),
curr_computation_id_(0),
is_closed_(false),
minimum_batch_size_(minimum_batch_size),
maximum_batch_size_(maximum_batch_size),
timeout_(std::move(timeout)) {}
string DebugString() override {
mutex_lock l(mu_);
return strings::StrCat("Batcher with ", inputs_.size(), " waiting inputs.");
}
void Compute(OpKernelContext* context, const OpInputList& input_list,
DoneCallback callback);
void GetInputs(OpKernelContext* context, OpOutputList* output_list);
void SetOutputs(OpKernelContext* context, const OpInputList& input_list,
int64 computation_id);
void Close(OpKernelContext* context);
private:
class Input {
public:
Input(OpKernelContext* context, const OpInputList& input_list,
DoneCallback callback)
: context_(context),
input_list_(input_list),
callback_(std::move(callback)) {}
// Moveable but not copyable.
Input(Input&& rhs)
: Input(rhs.context_, rhs.input_list_, std::move(rhs.callback_)) {
rhs.context_ = nullptr; // Mark invalid.
}
Input& operator=(Input&& rhs) {
this->context_ = rhs.context_;
this->input_list_ = rhs.input_list_;
this->callback_ = std::move(rhs.callback_);
rhs.context_ = nullptr; // Mark invalid.
return *this;
}
OpKernelContext* context() const {
CHECK(is_valid());
return context_;
}
const OpInputList& input_list() const {
CHECK(is_valid());
return input_list_;
}
bool is_valid() const { return context_ != nullptr; }
void Done() {
CHECK(is_valid());
// After callback is called, context_, input_list_ and callback_ becomes
// invalid and shouldn't be used.
context_ = nullptr;
callback_();
}
private:
// Not owned.
OpKernelContext* context_;
OpInputList input_list_;
DoneCallback callback_;
};
void CancelInput(Input* input) EXCLUSIVE_LOCKS_REQUIRED(mu_);
void GetInputsInternal(OpKernelContext* context, OpOutputList* output_list)
EXCLUSIVE_LOCKS_REQUIRED(mu_);
void SetOutputsInternal(OpKernelContext* context,
const OpInputList& input_list, int64 computation_id)
EXCLUSIVE_LOCKS_REQUIRED(mu_);
// Cancels all pending Compute ops and marks the batcher closed.
void CancelAndClose(OpKernelContext* context) EXCLUSIVE_LOCKS_REQUIRED(mu_);
mutex mu_;
condition_variable full_batch_or_cancelled_cond_var_;
// A counter of all batched computations that have been started that is used
// to create a unique id for each batched computation.
int64 curr_computation_id_ GUARDED_BY(mu_);
// Inputs waiting to be computed.
std::deque<Input> inputs_ GUARDED_BY(mu_);
// Batches that are currently being computed. Maps computation_id to a batch
// of inputs.
gtl::FlatMap<int64, std::vector<Input>> being_computed_ GUARDED_BY(mu_);
// Whether the Batcher has been closed (happens when there is an error or
// Close() has been called.)
bool is_closed_ GUARDED_BY(mu_);
const int32 minimum_batch_size_;
const int32 maximum_batch_size_;
const gtl::optional<std::chrono::milliseconds> timeout_;
TF_DISALLOW_COPY_AND_ASSIGN(Batcher);
};
void Batcher::Compute(OpKernelContext* context, const OpInputList& input_list,
DoneCallback callback) {
bool should_notify;
{
mutex_lock l(mu_);
OP_REQUIRES_ASYNC(context, !is_closed_,
errors::Cancelled("Batcher is closed"), callback);
// Add the inputs to the list of inputs.
inputs_.emplace_back(context, input_list, std::move(callback));
should_notify = inputs_.size() >= minimum_batch_size_;
}
if (should_notify) {
// If a GetInputs operation is blocked, wake it up.
full_batch_or_cancelled_cond_var_.notify_one();
}
}
void Batcher::GetInputs(OpKernelContext* context, OpOutputList* output_list) {
CancellationManager* cm = context->cancellation_manager();
CancellationToken token = cm->get_cancellation_token();
bool is_cancelled_or_cancelling = !cm->RegisterCallback(
token, [this]() { full_batch_or_cancelled_cond_var_.notify_all(); });
mutex_lock l(mu_);
std::cv_status status = std::cv_status::no_timeout;
// Wait for data if the input list has fewer samples than `minimum_batch_size`
// (or non-empty when a timeout has occurred), for cancellation of the
// operation or for the batcher to be closed.
while (((status == std::cv_status::timeout && inputs_.empty()) ||
(status == std::cv_status::no_timeout &&
inputs_.size() < minimum_batch_size_)) &&
!is_cancelled_or_cancelling && !is_closed_) {
// Using a timeout to make sure the operation always completes after a while
// when there isn't enough samples and for the unlikely case where the
// operation is being cancelled between checking if it has been cancelled
// and calling wait_for().
if (timeout_) {
status = full_batch_or_cancelled_cond_var_.wait_for(l, *timeout_);
} else {
// Timeout is only used to check for cancellation as described in the
// comment above.
full_batch_or_cancelled_cond_var_.wait_for(
l, std::chrono::milliseconds(100));
}
is_cancelled_or_cancelling = cm->IsCancelled();
}
if (is_closed_) {
context->SetStatus(errors::Cancelled("Batcher is closed"));
} else if (is_cancelled_or_cancelling) {
context->SetStatus(errors::Cancelled("GetInputs operation was cancelled"));
} else {
GetInputsInternal(context, output_list);
}
if (!context->status().ok()) {
CancelAndClose(context);
}
}
void Batcher::GetInputsInternal(OpKernelContext* context,
OpOutputList* output_list) {
int64 batch_size = std::min<int64>(inputs_.size(), maximum_batch_size_);
size_t num_tensors = inputs_.front().input_list().size();
// Allocate output tensors.
std::vector<Tensor*> output_tensors(num_tensors);
for (size_t i = 0; i < num_tensors; ++i) {
TensorShape shape = inputs_.front().input_list()[i].shape();
OP_REQUIRES(
context, shape.dim_size(0) == 1,
errors::InvalidArgument("Batcher requires batch size 1 but was ",
shape.dim_size(0)));
shape.set_dim(0, batch_size);
OP_REQUIRES_OK(context,
output_list->allocate(i, shape, &output_tensors[i]));
}
auto work = [this, &context, &output_tensors, num_tensors](
int64 start, int64 end) EXCLUSIVE_LOCKS_REQUIRED(mu_) {
for (int64 j = start; j < end; ++j) {
for (size_t i = 0; i < num_tensors; ++i) {
OP_REQUIRES(context,
inputs_[0].input_list()[i].shape() ==
inputs_[j].input_list()[i].shape(),
errors::InvalidArgument(
"Shapes of inputs much be equal. Shapes observed: ",
inputs_[0].input_list()[i].shape().DebugString(), ", ",
inputs_[j].input_list()[i].shape().DebugString()));
OP_REQUIRES_OK(context,
tensorflow::batch_util::CopyElementToSlice(
inputs_[j].input_list()[i], output_tensors[i], j));
}
}
};
auto worker_threads = context->device()->tensorflow_cpu_worker_threads();
Shard(worker_threads->num_threads, worker_threads->workers, batch_size, 10,
work);
// New unique computation id.
int64 new_computation_id = curr_computation_id_++;
Tensor* computation_id_t = nullptr;
OP_REQUIRES_OK(context,
context->allocate_output("computation_id", TensorShape({}),
&computation_id_t));
computation_id_t->scalar<int64>()() = new_computation_id;
// Move the batch of inputs into a list for the new computation.
auto iter = std::make_move_iterator(inputs_.begin());
being_computed_.emplace(new_computation_id,
std::vector<Input>{iter, iter + batch_size});
inputs_.erase(inputs_.begin(), inputs_.begin() + batch_size);
}
void Batcher::SetOutputs(OpKernelContext* context,
const OpInputList& input_list, int64 computation_id) {
mutex_lock l(mu_);
SetOutputsInternal(context, input_list, computation_id);
if (!context->status().ok()) {
CancelAndClose(context);
}
}
void Batcher::SetOutputsInternal(OpKernelContext* context,
const OpInputList& input_list,
int64 computation_id) {
OP_REQUIRES(context, !is_closed_, errors::Cancelled("Batcher is closed"));
auto search = being_computed_.find(computation_id);
OP_REQUIRES(
context, search != being_computed_.end(),
errors::InvalidArgument("Invalid computation id. Id: ", computation_id));
auto& computation_input_list = search->second;
int64 expected_batch_size = computation_input_list.size();
for (const Tensor& tensor : input_list) {
OP_REQUIRES(
context, tensor.shape().dims() > 0,
errors::InvalidArgument(
"Output shape must have a batch dimension. Shape observed: ",
tensor.shape().DebugString()));
OP_REQUIRES(
context, tensor.shape().dim_size(0) == expected_batch_size,
errors::InvalidArgument("Output shape must have the same batch "
"dimension as the input batch size. Expected: ",
expected_batch_size,
" Observed: ", tensor.shape().dim_size(0)));
}
auto work = [this, &input_list, &context, &computation_input_list](
int64 start, int64 end) EXCLUSIVE_LOCKS_REQUIRED(mu_) {
for (int64 j = start; j < end; ++j) {
Input& input = computation_input_list[j];
for (size_t i = 0; i < input_list.size(); ++i) {
TensorShape shape = input_list[i].shape();
shape.set_dim(0, 1);
Tensor* output_tensor;
OP_REQUIRES_OK(context, input.context()->allocate_output(
i, shape, &output_tensor));
OP_REQUIRES_OK(context, tensorflow::batch_util::CopySliceToElement(
input_list[i], output_tensor, j));
}
input.Done();
}
};
auto worker_threads = context->device()->tensorflow_cpu_worker_threads();
Shard(worker_threads->num_threads, worker_threads->workers,
expected_batch_size, 50000, work);
being_computed_.erase(computation_id);
}
void Batcher::Close(OpKernelContext* context) {
{
mutex_lock l(mu_);
CancelAndClose(context);
}
// Cancel all running GetInputs operations.
full_batch_or_cancelled_cond_var_.notify_all();
}
void Batcher::CancelInput(Batcher::Input* input) {
// Some may already have had their outputs set and the callback called so
// they should be skipped.
if (!input->is_valid()) {
return;
}
input->context()->CtxFailure(errors::Cancelled("Compute was cancelled"));
input->Done();
}
void Batcher::CancelAndClose(OpKernelContext* context) {
// Something went wrong or the batcher was requested to close. All the waiting
// Compute ops should be cancelled.
if (is_closed_) {
return;
}
for (auto& input : inputs_) {
CancelInput(&input);
}
for (auto& p : being_computed_) {
for (auto& input : p.second) {
CancelInput(&input);
}
}
is_closed_ = true; // Causes future Compute operations to be cancelled.
}
class BatcherHandleOp : public ResourceOpKernel<Batcher> {
public:
explicit BatcherHandleOp(OpKernelConstruction* context)
: ResourceOpKernel(context) {
OP_REQUIRES_OK(
context, context->GetAttr("minimum_batch_size", &minimum_batch_size_));
OP_REQUIRES_OK(
context, context->GetAttr("maximum_batch_size", &maximum_batch_size_));
OP_REQUIRES_OK(context, context->GetAttr("timeout_ms", &timeout_ms_));
}
private:
Status CreateResource(Batcher** ret) override EXCLUSIVE_LOCKS_REQUIRED(mu_) {
gtl::optional<std::chrono::milliseconds> timeout;
if (timeout_ms_ != -1) {
timeout = std::chrono::milliseconds(timeout_ms_);
}
*ret = new Batcher(minimum_batch_size_, maximum_batch_size_, timeout);
return Status::OK();
}
int32 minimum_batch_size_;
int32 maximum_batch_size_;
int32 timeout_ms_;
TF_DISALLOW_COPY_AND_ASSIGN(BatcherHandleOp);
};
class ComputeOp : public AsyncOpKernel {
public:
explicit ComputeOp(OpKernelConstruction* context) : AsyncOpKernel(context) {}
void ComputeAsync(OpKernelContext* context, DoneCallback callback) override {
Batcher* batcher;
OP_REQUIRES_OK(context, LookupResource(context, HandleFromInput(context, 0),
&batcher));
OpInputList input_list;
OP_REQUIRES_OK(context, context->input_list("input_list", &input_list));
batcher->Compute(context, input_list, std::move(callback));
}
private:
TF_DISALLOW_COPY_AND_ASSIGN(ComputeOp);
};
class GetInputsOp : public OpKernel {
public:
explicit GetInputsOp(OpKernelConstruction* context) : OpKernel(context) {}
void Compute(OpKernelContext* context) override {
Batcher* batcher;
OP_REQUIRES_OK(context, LookupResource(context, HandleFromInput(context, 0),
&batcher));
OpOutputList output_list;
OP_REQUIRES_OK(context, context->output_list("output_list", &output_list));
batcher->GetInputs(context, &output_list);
}
private:
TF_DISALLOW_COPY_AND_ASSIGN(GetInputsOp);
};
class SetOutputsOp : public OpKernel {
public:
explicit SetOutputsOp(OpKernelConstruction* context) : OpKernel(context) {}
void Compute(OpKernelContext* context) override {
Batcher* batcher;
OP_REQUIRES_OK(context, LookupResource(context, HandleFromInput(context, 0),
&batcher));
OpInputList input_list;
OP_REQUIRES_OK(context, context->input_list("input_list", &input_list));
const Tensor* computation_id;
OP_REQUIRES_OK(context, context->input("computation_id", &computation_id));
batcher->SetOutputs(context, input_list, computation_id->scalar<int64>()());
}
private:
TF_DISALLOW_COPY_AND_ASSIGN(SetOutputsOp);
};
class CloseOp : public OpKernel {
public:
explicit CloseOp(OpKernelConstruction* context) : OpKernel(context) {}
void Compute(OpKernelContext* context) override {
Batcher* batcher;
OP_REQUIRES_OK(context, LookupResource(context, HandleFromInput(context, 0),
&batcher));
batcher->Close(context);
}
private:
TF_DISALLOW_COPY_AND_ASSIGN(CloseOp);
};
REGISTER_KERNEL_BUILDER(Name("Batcher").Device(DEVICE_CPU), BatcherHandleOp);
REGISTER_KERNEL_BUILDER(Name("BatcherCompute").Device(DEVICE_CPU), ComputeOp);
REGISTER_KERNEL_BUILDER(Name("BatcherGetInputs").Device(DEVICE_CPU),
GetInputsOp);
REGISTER_KERNEL_BUILDER(Name("BatcherSetOutputs").Device(DEVICE_CPU),
SetOutputsOp);
REGISTER_KERNEL_BUILDER(Name("BatcherClose").Device(DEVICE_CPU), CloseOp);
} // namespace
} // namespace tensorflow