blob: 3129ae32e4031e9b7c7c6963cc510effdbf37f85 [file] [log] [blame]
// Copyright 2014 The Chromium Authors. All rights reserved.
// Use of this source code is governed by a BSD-style license that can be
// found in the LICENSE file.
#include "ui/events/event_rewriter.h"
#include <list>
#include <map>
#include <set>
#include <utility>
#include "testing/gtest/include/gtest/gtest.h"
#include "ui/events/test/test_event_processor.h"
namespace ui {
namespace {
// To test the handling of |EventRewriter|s through |EventSource|,
// we rewrite and test event types.
class TestEvent : public Event {
public:
explicit TestEvent(EventType type)
: Event(type, base::TimeDelta(), 0), unique_id_(next_unique_id_++) {}
~TestEvent() override {}
int unique_id() const { return unique_id_; }
private:
static int next_unique_id_;
int unique_id_;
};
int TestEvent::next_unique_id_ = 0;
// TestEventRewriteProcessor is set up with a sequence of event types,
// and fails if the events received via OnEventFromSource() do not match
// this sequence. These expected event types are consumed on receipt.
class TestEventRewriteProcessor : public test::TestEventProcessor {
public:
TestEventRewriteProcessor() {}
~TestEventRewriteProcessor() override { CheckAllReceived(); }
void AddExpectedEvent(EventType type) { expected_events_.push_back(type); }
// Test that all expected events have been received.
void CheckAllReceived() { EXPECT_TRUE(expected_events_.empty()); }
// EventProcessor:
EventDispatchDetails OnEventFromSource(Event* event) override {
EXPECT_FALSE(expected_events_.empty());
EXPECT_EQ(expected_events_.front(), event->type());
expected_events_.pop_front();
return EventDispatchDetails();
}
private:
std::list<EventType> expected_events_;
DISALLOW_COPY_AND_ASSIGN(TestEventRewriteProcessor);
};
// Trivial EventSource that does nothing but send events.
class TestEventRewriteSource : public EventSource {
public:
explicit TestEventRewriteSource(EventProcessor* processor)
: processor_(processor) {}
EventProcessor* GetEventProcessor() override { return processor_; }
void Send(EventType type) {
scoped_ptr<Event> event(new TestEvent(type));
(void)SendEventToProcessor(event.get());
}
private:
EventProcessor* processor_;
};
// This EventRewriter always returns the same status, and if rewriting, the
// same event type; it is used to test simple rewriting, and rewriter addition,
// removal, and sequencing. Consequently EVENT_REWRITE_DISPATCH_ANOTHER is not
// supported here (calls to NextDispatchEvent() would continue indefinitely).
class TestConstantEventRewriter : public EventRewriter {
public:
TestConstantEventRewriter(EventRewriteStatus status, EventType type)
: status_(status), type_(type) {
CHECK_NE(EVENT_REWRITE_DISPATCH_ANOTHER, status);
}
EventRewriteStatus RewriteEvent(const Event& event,
scoped_ptr<Event>* rewritten_event)
override {
if (status_ == EVENT_REWRITE_REWRITTEN)
rewritten_event->reset(new TestEvent(type_));
return status_;
}
EventRewriteStatus NextDispatchEvent(const Event& last_event,
scoped_ptr<Event>* new_event) override {
NOTREACHED();
return status_;
}
private:
EventRewriteStatus status_;
EventType type_;
};
// This EventRewriter runs a simple state machine; it is used to test
// EVENT_REWRITE_DISPATCH_ANOTHER.
class TestStateMachineEventRewriter : public EventRewriter {
public:
TestStateMachineEventRewriter() : last_rewritten_event_(0), state_(0) {}
void AddRule(int from_state, EventType from_type,
int to_state, EventType to_type, EventRewriteStatus to_status) {
RewriteResult r = {to_state, to_type, to_status};
rules_.insert(std::pair<RewriteCase, RewriteResult>(
RewriteCase(from_state, from_type), r));
}
EventRewriteStatus RewriteEvent(const Event& event,
scoped_ptr<Event>* rewritten_event) override {
RewriteRules::iterator find =
rules_.find(RewriteCase(state_, event.type()));
if (find == rules_.end())
return EVENT_REWRITE_CONTINUE;
if ((find->second.status == EVENT_REWRITE_REWRITTEN) ||
(find->second.status == EVENT_REWRITE_DISPATCH_ANOTHER)) {
last_rewritten_event_ = new TestEvent(find->second.type);
rewritten_event->reset(last_rewritten_event_);
} else {
last_rewritten_event_ = 0;
}
state_ = find->second.state;
return find->second.status;
}
EventRewriteStatus NextDispatchEvent(const Event& last_event,
scoped_ptr<Event>* new_event) override {
EXPECT_TRUE(last_rewritten_event_);
const TestEvent* arg_last = static_cast<const TestEvent*>(&last_event);
EXPECT_EQ(last_rewritten_event_->unique_id(), arg_last->unique_id());
const TestEvent* arg_new = static_cast<const TestEvent*>(new_event->get());
EXPECT_FALSE(arg_new && arg_last->unique_id() == arg_new->unique_id());
return RewriteEvent(last_event, new_event);
}
private:
typedef std::pair<int, EventType> RewriteCase;
struct RewriteResult {
int state;
EventType type;
EventRewriteStatus status;
};
typedef std::map<RewriteCase, RewriteResult> RewriteRules;
RewriteRules rules_;
TestEvent* last_rewritten_event_;
int state_;
};
} // namespace
TEST(EventRewriterTest, EventRewriting) {
// TestEventRewriter r0 always rewrites events to ET_CANCEL_MODE;
// it is placed at the beginning of the chain and later removed,
// to verify that rewriter removal works.
TestConstantEventRewriter r0(EVENT_REWRITE_REWRITTEN, ET_CANCEL_MODE);
// TestEventRewriter r1 always returns EVENT_REWRITE_CONTINUE;
// it is placed at the beginning of the chain to verify that a
// later rewriter sees the events.
TestConstantEventRewriter r1(EVENT_REWRITE_CONTINUE, ET_UNKNOWN);
// TestEventRewriter r2 has a state machine, primarily to test
// |EVENT_REWRITE_DISPATCH_ANOTHER|.
TestStateMachineEventRewriter r2;
// TestEventRewriter r3 always rewrites events to ET_CANCEL_MODE;
// it is placed at the end of the chain to verify that previously
// rewritten events are not passed further down the chain.
TestConstantEventRewriter r3(EVENT_REWRITE_REWRITTEN, ET_CANCEL_MODE);
TestEventRewriteProcessor p;
TestEventRewriteSource s(&p);
s.AddEventRewriter(&r0);
s.AddEventRewriter(&r1);
s.AddEventRewriter(&r2);
// These events should be rewritten by r0 to ET_CANCEL_MODE.
p.AddExpectedEvent(ET_CANCEL_MODE);
s.Send(ET_MOUSE_DRAGGED);
p.AddExpectedEvent(ET_CANCEL_MODE);
s.Send(ET_MOUSE_PRESSED);
p.CheckAllReceived();
// Remove r0, and verify that it's gone and that events make it through.
s.AddEventRewriter(&r3);
s.RemoveEventRewriter(&r0);
r2.AddRule(0, ET_SCROLL_FLING_START,
0, ET_SCROLL_FLING_CANCEL, EVENT_REWRITE_REWRITTEN);
p.AddExpectedEvent(ET_SCROLL_FLING_CANCEL);
s.Send(ET_SCROLL_FLING_START);
p.CheckAllReceived();
s.RemoveEventRewriter(&r3);
// Verify EVENT_REWRITE_DISPATCH_ANOTHER using a state machine
// (that happens to be analogous to sticky keys).
r2.AddRule(0, ET_KEY_PRESSED,
1, ET_KEY_PRESSED, EVENT_REWRITE_CONTINUE);
r2.AddRule(1, ET_MOUSE_PRESSED,
0, ET_MOUSE_PRESSED, EVENT_REWRITE_CONTINUE);
r2.AddRule(1, ET_KEY_RELEASED,
2, ET_KEY_RELEASED, EVENT_REWRITE_DISCARD);
r2.AddRule(2, ET_MOUSE_RELEASED,
3, ET_MOUSE_RELEASED, EVENT_REWRITE_DISPATCH_ANOTHER);
r2.AddRule(3, ET_MOUSE_RELEASED,
0, ET_KEY_RELEASED, EVENT_REWRITE_REWRITTEN);
p.AddExpectedEvent(ET_KEY_PRESSED);
s.Send(ET_KEY_PRESSED);
s.Send(ET_KEY_RELEASED);
p.AddExpectedEvent(ET_MOUSE_PRESSED);
s.Send(ET_MOUSE_PRESSED);
// Removing rewriters r1 and r3 shouldn't affect r2.
s.RemoveEventRewriter(&r1);
s.RemoveEventRewriter(&r3);
// Continue with the state-based rewriting.
p.AddExpectedEvent(ET_MOUSE_RELEASED);
p.AddExpectedEvent(ET_KEY_RELEASED);
s.Send(ET_MOUSE_RELEASED);
p.CheckAllReceived();
}
} // namespace ui