//
// Copyright (C) 2009 The Android Open Source Project
//
// 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.
//
#ifndef UPDATE_ENGINE_COMMON_ACTION_H_
#define UPDATE_ENGINE_COMMON_ACTION_H_
#include <stdio.h>
#include <memory>
#include <string>
#include <base/logging.h>
#include <base/macros.h>
#include "update_engine/common/action_pipe.h"
#include "update_engine/common/action_processor.h"
// The structure of these classes (Action, ActionPipe, ActionProcessor, etc.)
// is based on the KSAction* classes from the Google Update Engine code at
// http://code.google.com/p/update-engine/ . The author of this file sends
// a big thanks to that team for their high quality design, implementation,
// and documentation.
//
// Readers may want to consult this wiki page from the Update Engine site:
// http://code.google.com/p/update-engine/wiki/ActionProcessor
// Although it's referring to the Objective-C KSAction* classes, much
// applies here as well.
//
// How it works:
//
// First off, there is only one thread and all I/O should be asynchronous.
// A message loop blocks whenever there is no work to be done. This happens
// where there is no CPU work to be done and no I/O ready to transfer in or
// out. Two kinds of events can wake up the message loop: timer alarm or file
// descriptors. If either of these happens, the message loop finds out the owner
// of what fired and calls the appropriate code to handle it. As such, all the
// code in the Action* classes and the code that is calls is non-blocking.
//
// An ActionProcessor contains a queue of Actions to perform. When
// ActionProcessor::StartProcessing() is called, it executes the first action.
// Each action tells the processor when it has completed, which causes the
// Processor to execute the next action. ActionProcessor may have a delegate
// (an object of type ActionProcessorDelegate). If it does, the delegate
// is called to be notified of events as they happen.
//
// ActionPipe classes
//
// See action_pipe.h
//
// ActionTraits
//
// We need to use an extra class ActionTraits. ActionTraits is a simple
// templated class that contains only two typedefs: OutputObjectType and
// InputObjectType. Each action class also has two typedefs of the same name
// that are of the same type. So, to get the input/output types of, e.g., the
// DownloadAction class, we look at the type of
// DownloadAction::InputObjectType.
//
// Each concrete Action class derives from Action<T>. This means that during
// template instantiation of Action<T>, T is declared but not defined, which
// means that T::InputObjectType (and OutputObjectType) is not defined.
// However, the traits class is constructed in such a way that it will be
// template instantiated first, so Action<T> *can* find the types it needs by
// consulting ActionTraits<T>::InputObjectType (and OutputObjectType).
// This is why the ActionTraits classes are needed.
namespace chromeos_update_engine {
// It is handy to have a non-templated base class of all Actions.
class AbstractAction {
public:
AbstractAction() : processor_(nullptr) {}
virtual ~AbstractAction() = default;
// Begin performing the action. Since this code is asynchronous, when this
// method returns, it means only that the action has started, not necessarily
// completed. However, it's acceptable for this method to perform the
// action synchronously; Action authors should understand the implications
// of synchronously performing, though, because this is a single-threaded
// app, the entire process will be blocked while the action performs.
//
// When the action is complete, it must call
// ActionProcessor::ActionComplete(this); to notify the processor that it's
// done.
virtual void PerformAction() = 0;
// Called on ActionProcess::ActionComplete() by ActionProcessor.
virtual void ActionCompleted(ErrorCode code) {}
// Called by the ActionProcessor to tell this Action which processor
// it belongs to.
void SetProcessor(ActionProcessor* processor) {
if (processor)
CHECK(!processor_);
else
CHECK(processor_);
processor_ = processor;
}
// Returns true iff the action is the current action of its ActionProcessor.
bool IsRunning() const {
if (!processor_)
return false;
return processor_->current_action() == this;
}
// Called on asynchronous actions if canceled. Actions may implement if
// there's any cleanup to do. There is no need to call
// ActionProcessor::ActionComplete() because the processor knows this
// action is terminating.
// Only the ActionProcessor should call this.
virtual void TerminateProcessing() {}
// Called on asynchronous actions if the processing is suspended and resumed,
// respectively. These methods are called by the ActionProcessor and should
// not be explicitly called.
// The action may still call ActionCompleted() once the action is completed
// while the processing is suspended, for example if suspend/resume is not
// implemented for the given action.
virtual void SuspendAction() {}
virtual void ResumeAction() {}
// These methods are useful for debugging. TODO(adlr): consider using
// std::type_info for this?
// Type() returns a string of the Action type. I.e., for DownloadAction,
// Type() would return "DownloadAction".
virtual std::string Type() const = 0;
protected:
// A weak pointer to the processor that owns this Action.
ActionProcessor* processor_;
};
// Forward declare a couple classes we use.
template<typename T>
class ActionPipe;
template<typename T>
class ActionTraits;
template<typename SubClass>
class Action : public AbstractAction {
public:
~Action() override {}
// Attaches an input pipe to this Action. This is optional; an Action
// doesn't need to have an input pipe. The input pipe must be of the type
// of object that this class expects.
// This is generally called by ActionPipe::Bond()
void set_in_pipe(
// this type is a fancy way of saying: a shared_ptr to an
// ActionPipe<InputObjectType>.
const std::shared_ptr<ActionPipe<
typename ActionTraits<SubClass>::InputObjectType>>& in_pipe) {
in_pipe_ = in_pipe;
}
// Attaches an output pipe to this Action. This is optional; an Action
// doesn't need to have an output pipe. The output pipe must be of the type
// of object that this class expects.
// This is generally called by ActionPipe::Bond()
void set_out_pipe(
// this type is a fancy way of saying: a shared_ptr to an
// ActionPipe<OutputObjectType>.
const std::shared_ptr<ActionPipe<
typename ActionTraits<SubClass>::OutputObjectType>>& out_pipe) {
out_pipe_ = out_pipe;
}
// Returns true iff there is an associated input pipe. If there's an input
// pipe, there's an input object, but it may have been constructed with the
// default ctor if the previous action didn't call SetOutputObject().
bool HasInputObject() const { return in_pipe_.get(); }
// returns a const reference to the object in the input pipe.
const typename ActionTraits<SubClass>::InputObjectType& GetInputObject()
const {
CHECK(HasInputObject());
return in_pipe_->contents();
}
// Returns true iff there's an output pipe.
bool HasOutputPipe() const {
return out_pipe_.get();
}
// Copies the object passed into the output pipe. It will be accessible to
// the next Action via that action's input pipe (which is the same as this
// Action's output pipe).
void SetOutputObject(
const typename ActionTraits<SubClass>::OutputObjectType& out_obj) {
CHECK(HasOutputPipe());
out_pipe_->set_contents(out_obj);
}
// Returns a reference to the object sitting in the output pipe.
const typename ActionTraits<SubClass>::OutputObjectType& GetOutputObject() {
CHECK(HasOutputPipe());
return out_pipe_->contents();
}
protected:
// We use a shared_ptr to the pipe. shared_ptr objects destroy what they
// point to when the last such shared_ptr object dies. We consider the
// Actions on either end of a pipe to "own" the pipe. When the last Action
// of the two dies, the ActionPipe will die, too.
std::shared_ptr<ActionPipe<typename ActionTraits<SubClass>::InputObjectType>>
in_pipe_;
std::shared_ptr<ActionPipe<typename ActionTraits<SubClass>::OutputObjectType>>
out_pipe_;
};
}; // namespace chromeos_update_engine
#endif // UPDATE_ENGINE_COMMON_ACTION_H_