verdnatura-chat/ios/Pods/Flipper-RSocket/rsocket/RSocketRequester.cpp

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// Copyright (c) Facebook, Inc. and its affiliates.
//
// 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
//
// http://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.
#include "rsocket/RSocketRequester.h"
#include <folly/ExceptionWrapper.h>
#include "rsocket/internal/ScheduledSingleObserver.h"
#include "rsocket/internal/ScheduledSubscriber.h"
#include "yarpl/Flowable.h"
#include "yarpl/single/SingleSubscriptions.h"
using namespace folly;
namespace rsocket {
namespace {
template <class Fn>
void runOnCorrectThread(folly::EventBase& evb, Fn fn) {
if (evb.isInEventBaseThread()) {
fn();
} else {
evb.runInEventBaseThread(std::move(fn));
}
}
} // namespace
RSocketRequester::RSocketRequester(
std::shared_ptr<RSocketStateMachine> srs,
EventBase& eventBase)
: stateMachine_{std::move(srs)}, eventBase_{&eventBase} {}
RSocketRequester::~RSocketRequester() {
VLOG(1) << "Destroying RSocketRequester";
}
void RSocketRequester::closeSocket() {
eventBase_->runInEventBaseThread([stateMachine = std::move(stateMachine_)] {
VLOG(2) << "Closing RSocketStateMachine on EventBase";
stateMachine->close({}, StreamCompletionSignal::SOCKET_CLOSED);
});
}
std::shared_ptr<yarpl::flowable::Flowable<rsocket::Payload>>
RSocketRequester::requestChannel(
std::shared_ptr<yarpl::flowable::Flowable<rsocket::Payload>>
requestStream) {
return requestChannel({}, false, std::move(requestStream));
}
std::shared_ptr<yarpl::flowable::Flowable<rsocket::Payload>>
RSocketRequester::requestChannel(
Payload request,
std::shared_ptr<yarpl::flowable::Flowable<rsocket::Payload>>
requestStream) {
return requestChannel(std::move(request), true, std::move(requestStream));
}
std::shared_ptr<yarpl::flowable::Flowable<rsocket::Payload>>
RSocketRequester::requestChannel(
Payload request,
bool hasInitialRequest,
std::shared_ptr<yarpl::flowable::Flowable<rsocket::Payload>>
requestStreamFlowable) {
CHECK(stateMachine_);
return yarpl::flowable::internal::flowableFromSubscriber<Payload>(
[eb = eventBase_,
req = std::move(request),
hasInitialRequest,
requestStream = std::move(requestStreamFlowable),
srs = stateMachine_](
std::shared_ptr<yarpl::flowable::Subscriber<Payload>> subscriber) {
auto lambda = [eb,
r = req.clone(),
hasInitialRequest,
requestStream,
srs,
subs = std::move(subscriber)]() mutable {
auto scheduled =
std::make_shared<ScheduledSubscriptionSubscriber<Payload>>(
std::move(subs), *eb);
auto responseSink = srs->requestChannel(
std::move(r), hasInitialRequest, std::move(scheduled));
// responseSink is wrapped with thread scheduling
// so all emissions happen on the right thread.
// If we don't get a responseSink back, that means that
// the requesting peer wasn't connected (or similar error)
// and the Flowable it gets back will immediately call onError.
if (responseSink) {
auto scheduledResponse =
std::make_shared<ScheduledSubscriber<Payload>>(
std::move(responseSink), *eb);
requestStream->subscribe(std::move(scheduledResponse));
}
};
runOnCorrectThread(*eb, std::move(lambda));
});
}
std::shared_ptr<yarpl::flowable::Flowable<Payload>>
RSocketRequester::requestStream(Payload request) {
CHECK(stateMachine_);
return yarpl::flowable::internal::flowableFromSubscriber<Payload>(
[eb = eventBase_, req = std::move(request), srs = stateMachine_](
std::shared_ptr<yarpl::flowable::Subscriber<Payload>> subscriber) {
auto lambda =
[eb, r = req.clone(), srs, subs = std::move(subscriber)]() mutable {
auto scheduled =
std::make_shared<ScheduledSubscriptionSubscriber<Payload>>(
std::move(subs), *eb);
srs->requestStream(std::move(r), std::move(scheduled));
};
runOnCorrectThread(*eb, std::move(lambda));
});
}
std::shared_ptr<yarpl::single::Single<rsocket::Payload>>
RSocketRequester::requestResponse(Payload request) {
CHECK(stateMachine_);
return yarpl::single::Single<Payload>::create(
[eb = eventBase_, req = std::move(request), srs = stateMachine_](
std::shared_ptr<yarpl::single::SingleObserver<Payload>> observer) {
auto lambda = [eb,
r = req.clone(),
srs,
obs = std::move(observer)]() mutable {
auto scheduled =
std::make_shared<ScheduledSubscriptionSingleObserver<Payload>>(
std::move(obs), *eb);
srs->requestResponse(std::move(r), std::move(scheduled));
};
runOnCorrectThread(*eb, std::move(lambda));
});
}
std::shared_ptr<yarpl::single::Single<void>> RSocketRequester::fireAndForget(
rsocket::Payload request) {
CHECK(stateMachine_);
return yarpl::single::Single<void>::create(
[eb = eventBase_, req = std::move(request), srs = stateMachine_](
std::shared_ptr<yarpl::single::SingleObserverBase<void>> subscriber) {
auto lambda =
[r = req.clone(), srs, subs = std::move(subscriber)]() mutable {
// TODO: Pass in SingleSubscriber for underlying layers to call
// onSuccess/onError once put on network.
srs->fireAndForget(std::move(r));
subs->onSubscribe(yarpl::single::SingleSubscriptions::empty());
subs->onSuccess();
};
runOnCorrectThread(*eb, std::move(lambda));
});
}
void RSocketRequester::metadataPush(std::unique_ptr<folly::IOBuf> metadata) {
CHECK(stateMachine_);
runOnCorrectThread(
*eventBase_, [srs = stateMachine_, meta = std::move(metadata)]() mutable {
srs->metadataPush(std::move(meta));
});
}
} // namespace rsocket