blob: 1804eaedee87adf1f35434fd924db81f9fb8e91c [file] [log] [blame]
// Copyright (c) 2013 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/base/x/selection_owner.h"
#include <algorithm>
#include "base/logging.h"
#include "ui/base/x/selection_utils.h"
#include "ui/base/x/x11_window_event_manager.h"
#include "ui/events/platform/x11/x11_event_source.h"
#include "ui/gfx/x/x11.h"
#include "ui/gfx/x/x11_atom_cache.h"
namespace ui {
const char kIncr[] = "INCR";
const char kSaveTargets[] = "SAVE_TARGETS";
const char kTargets[] = "TARGETS";
namespace {
const char kAtomPair[] = "ATOM_PAIR";
const char kMultiple[] = "MULTIPLE";
const char kTimestamp[] = "TIMESTAMP";
// The period of |incremental_transfer_abort_timer_|. Arbitrary but must be <=
// than kIncrementalTransferTimeoutMs.
const int KSelectionOwnerTimerPeriodMs = 1000;
// The amount of time to wait for the selection requestor to process the data
// sent by the selection owner before aborting an incremental data transfer.
const int kIncrementalTransferTimeoutMs = 10000;
static_assert(KSelectionOwnerTimerPeriodMs <= kIncrementalTransferTimeoutMs,
"timer period must be <= transfer timeout");
// Returns a conservative max size of the data we can pass into
// XChangeProperty(). Copied from GTK.
size_t GetMaxRequestSize(XDisplay* display) {
long extended_max_size = XExtendedMaxRequestSize(display);
long max_size =
(extended_max_size ? extended_max_size : XMaxRequestSize(display)) - 100;
return std::min(static_cast<long>(0x40000),
std::max(static_cast<long>(0), max_size));
}
// Gets the value of an atom pair array property. On success, true is returned
// and the value is stored in |value|.
bool GetAtomPairArrayProperty(XID window,
XAtom property,
std::vector<std::pair<XAtom,XAtom> >* value) {
XAtom type = x11::None;
int format = 0; // size in bits of each item in 'property'
unsigned long num_items = 0;
unsigned char* properties = NULL;
unsigned long remaining_bytes = 0;
int result = XGetWindowProperty(gfx::GetXDisplay(), window, property,
0, // offset into property data to
// read
(~0L), // entire array
x11::False, // deleted
AnyPropertyType, &type, &format, &num_items,
&remaining_bytes, &properties);
gfx::XScopedPtr<unsigned char> scoped_properties(properties);
if (result != x11::Success)
return false;
// GTK does not require |type| to be kAtomPair.
if (format != 32 || num_items % 2 != 0)
return false;
XAtom* atom_properties = reinterpret_cast<XAtom*>(properties);
value->clear();
for (size_t i = 0; i < num_items; i+=2)
value->push_back(std::make_pair(atom_properties[i], atom_properties[i+1]));
return true;
}
} // namespace
SelectionOwner::SelectionOwner(XDisplay* x_display,
XID x_window,
XAtom selection_name)
: x_display_(x_display),
x_window_(x_window),
selection_name_(selection_name),
max_request_size_(GetMaxRequestSize(x_display)) {}
SelectionOwner::~SelectionOwner() {
// If we are the selection owner, we need to release the selection so we
// don't receive further events. However, we don't call ClearSelectionOwner()
// because we don't want to do this indiscriminately.
if (XGetSelectionOwner(x_display_, selection_name_) == x_window_)
XSetSelectionOwner(x_display_, selection_name_, x11::None,
x11::CurrentTime);
}
void SelectionOwner::RetrieveTargets(std::vector<XAtom>* targets) {
for (auto it = format_map_.begin(); it != format_map_.end(); ++it) {
targets->push_back(it->first);
}
}
void SelectionOwner::TakeOwnershipOfSelection(
const SelectionFormatMap& data) {
acquired_selection_timestamp_ = X11EventSource::GetInstance()->GetTimestamp();
XSetSelectionOwner(x_display_, selection_name_, x_window_,
acquired_selection_timestamp_);
if (XGetSelectionOwner(x_display_, selection_name_) == x_window_) {
// The X server agrees that we are the selection owner. Commit our data.
format_map_ = data;
}
}
void SelectionOwner::ClearSelectionOwner() {
XSetSelectionOwner(x_display_, selection_name_, x11::None, x11::CurrentTime);
format_map_ = SelectionFormatMap();
}
void SelectionOwner::OnSelectionRequest(const XEvent& event) {
XID requestor = event.xselectionrequest.requestor;
XAtom requested_target = event.xselectionrequest.target;
XAtom requested_property = event.xselectionrequest.property;
// Incrementally build our selection. By default this is a refusal, and we'll
// override the parts indicating success in the different cases.
XEvent reply;
reply.xselection.type = SelectionNotify;
reply.xselection.requestor = requestor;
reply.xselection.selection = event.xselectionrequest.selection;
reply.xselection.target = requested_target;
reply.xselection.property = x11::None; // Indicates failure
reply.xselection.time = event.xselectionrequest.time;
if (requested_target == gfx::GetAtom(kMultiple)) {
// The contents of |requested_property| should be a list of
// <target,property> pairs.
std::vector<std::pair<XAtom,XAtom> > conversions;
if (GetAtomPairArrayProperty(requestor,
requested_property,
&conversions)) {
std::vector<XAtom> conversion_results;
for (size_t i = 0; i < conversions.size(); ++i) {
bool conversion_successful = ProcessTarget(conversions[i].first,
requestor,
conversions[i].second);
conversion_results.push_back(conversions[i].first);
conversion_results.push_back(
conversion_successful ? conversions[i].second : x11::None);
}
// Set the property to indicate which conversions succeeded. This matches
// what GTK does.
XChangeProperty(
x_display_, requestor, requested_property, gfx::GetAtom(kAtomPair),
32, PropModeReplace,
reinterpret_cast<const unsigned char*>(&conversion_results.front()),
conversion_results.size());
reply.xselection.property = requested_property;
}
} else {
if (ProcessTarget(requested_target, requestor, requested_property))
reply.xselection.property = requested_property;
}
// Send off the reply.
XSendEvent(x_display_, requestor, x11::False, 0, &reply);
}
void SelectionOwner::OnSelectionClear(const XEvent& event) {
DLOG(ERROR) << "SelectionClear";
// TODO(erg): If we receive a SelectionClear event while we're handling data,
// we need to delay clearing.
}
bool SelectionOwner::CanDispatchPropertyEvent(const XEvent& event) {
return event.xproperty.state == PropertyDelete &&
FindIncrementalTransferForEvent(event) != incremental_transfers_.end();
}
void SelectionOwner::OnPropertyEvent(const XEvent& event) {
auto it = FindIncrementalTransferForEvent(event);
if (it == incremental_transfers_.end())
return;
ProcessIncrementalTransfer(&(*it));
if (!it->data.get())
CompleteIncrementalTransfer(it);
}
bool SelectionOwner::ProcessTarget(XAtom target,
XID requestor,
XAtom property) {
XAtom multiple_atom = gfx::GetAtom(kMultiple);
XAtom save_targets_atom = gfx::GetAtom(kSaveTargets);
XAtom targets_atom = gfx::GetAtom(kTargets);
XAtom timestamp_atom = gfx::GetAtom(kTimestamp);
if (target == multiple_atom || target == save_targets_atom)
return false;
if (target == timestamp_atom) {
XChangeProperty(
x_display_, requestor, property, XA_INTEGER, 32, PropModeReplace,
reinterpret_cast<unsigned char*>(&acquired_selection_timestamp_), 1);
return true;
}
if (target == targets_atom) {
// We have been asked for TARGETS. Send an atom array back with the data
// types we support.
std::vector<XAtom> targets;
targets.push_back(timestamp_atom);
targets.push_back(targets_atom);
targets.push_back(save_targets_atom);
targets.push_back(multiple_atom);
RetrieveTargets(&targets);
XChangeProperty(x_display_, requestor, property, XA_ATOM, 32,
PropModeReplace,
reinterpret_cast<unsigned char*>(&targets.front()),
targets.size());
return true;
}
// Try to find the data type in map.
auto it = format_map_.find(target);
if (it != format_map_.end()) {
if (it->second->size() > max_request_size_) {
// We must send the data back in several chunks due to a limitation in
// the size of X requests. Notify the selection requestor that the data
// will be sent incrementally by returning data of type "INCR".
long length = it->second->size();
XChangeProperty(x_display_, requestor, property, gfx::GetAtom(kIncr), 32,
PropModeReplace,
reinterpret_cast<unsigned char*>(&length), 1);
// Wait for the selection requestor to indicate that it has processed
// the selection result before sending the first chunk of data. The
// selection requestor indicates this by deleting |property|.
base::TimeTicks timeout =
base::TimeTicks::Now() +
base::TimeDelta::FromMilliseconds(kIncrementalTransferTimeoutMs);
incremental_transfers_.push_back(IncrementalTransfer(
requestor, target, property,
std::make_unique<XScopedEventSelector>(requestor, PropertyChangeMask),
it->second, 0, timeout));
// Start a timer to abort the data transfer in case that the selection
// requestor does not support the INCR property or gets destroyed during
// the data transfer.
if (!incremental_transfer_abort_timer_.IsRunning()) {
incremental_transfer_abort_timer_.Start(
FROM_HERE,
base::TimeDelta::FromMilliseconds(KSelectionOwnerTimerPeriodMs),
this, &SelectionOwner::AbortStaleIncrementalTransfers);
}
} else {
XChangeProperty(
x_display_,
requestor,
property,
target,
8,
PropModeReplace,
const_cast<unsigned char*>(it->second->front()),
it->second->size());
}
return true;
}
// I would put error logging here, but GTK ignores TARGETS and spams us
// looking for its own internal types.
return false;
}
void SelectionOwner::ProcessIncrementalTransfer(IncrementalTransfer* transfer) {
size_t remaining = transfer->data->size() - transfer->offset;
size_t chunk_length = std::min(remaining, max_request_size_);
XChangeProperty(
x_display_,
transfer->window,
transfer->property,
transfer->target,
8,
PropModeReplace,
const_cast<unsigned char*>(transfer->data->front() + transfer->offset),
chunk_length);
transfer->offset += chunk_length;
transfer->timeout = base::TimeTicks::Now() +
base::TimeDelta::FromMilliseconds(kIncrementalTransferTimeoutMs);
// When offset == data->size(), we still need to transfer a zero-sized chunk
// to notify the selection requestor that the transfer is complete. Clear
// transfer->data once the zero-sized chunk is sent to indicate that state
// related to this data transfer can be cleared.
if (chunk_length == 0)
transfer->data = NULL;
}
void SelectionOwner::AbortStaleIncrementalTransfers() {
base::TimeTicks now = base::TimeTicks::Now();
for (int i = static_cast<int>(incremental_transfers_.size()) - 1;
i >= 0; --i) {
if (incremental_transfers_[i].timeout <= now)
CompleteIncrementalTransfer(incremental_transfers_.begin() + i);
}
}
void SelectionOwner::CompleteIncrementalTransfer(
std::vector<IncrementalTransfer>::iterator it) {
incremental_transfers_.erase(it);
if (incremental_transfers_.empty())
incremental_transfer_abort_timer_.Stop();
}
std::vector<SelectionOwner::IncrementalTransfer>::iterator
SelectionOwner::FindIncrementalTransferForEvent(const XEvent& event) {
for (auto it = incremental_transfers_.begin();
it != incremental_transfers_.end(); ++it) {
if (it->window == event.xproperty.window &&
it->property == event.xproperty.atom) {
return it;
}
}
return incremental_transfers_.end();
}
SelectionOwner::IncrementalTransfer::IncrementalTransfer(
XID window,
XAtom target,
XAtom property,
std::unique_ptr<XScopedEventSelector> event_selector,
const scoped_refptr<base::RefCountedMemory>& data,
int offset,
base::TimeTicks timeout)
: window(window),
target(target),
property(property),
event_selector(std::move(event_selector)),
data(data),
offset(offset),
timeout(timeout) {}
SelectionOwner::IncrementalTransfer::IncrementalTransfer(
IncrementalTransfer&& other) = default;
SelectionOwner::IncrementalTransfer& SelectionOwner::IncrementalTransfer::
operator=(IncrementalTransfer&&) = default;
SelectionOwner::IncrementalTransfer::~IncrementalTransfer() {
}
} // namespace ui