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fuchsia / fuchsia / refs/heads/sandbox/markdittmer/chunked-demand-paging / . / src / connectivity / bluetooth / core / bt-host / gap / peer.cc
blob: b8853dfe7557be9570790a40df98e88873058d96 [file] [log] [blame]
// Copyright 2017 The Fuchsia 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 "peer.h"
#include <zircon/assert.h>
#include "src/connectivity/bluetooth/core/bt-host/common/advertising_data.h"
#include "src/connectivity/bluetooth/core/bt-host/common/manufacturer_names.h"
#include "src/connectivity/bluetooth/core/bt-host/hci/low_energy_scanner.h"
#include "src/connectivity/bluetooth/core/bt-host/hci/util.h"
#include "src/lib/fxl/strings/string_printf.h"
namespace bt {
namespace gap {
std::string Peer::ConnectionStateToString(Peer::ConnectionState state) {
switch (state) {
case Peer::ConnectionState::kNotConnected:
return "not connected";
case Peer::ConnectionState::kInitializing:
return "connecting";
case Peer::ConnectionState::kConnected:
return "connected";
}
ZX_PANIC("invalid connection state %u", static_cast<unsigned int>(state));
return "(unknown)";
}
Peer::LowEnergyData::LowEnergyData(Peer* owner, inspect::Node node)
: peer_(owner),
node_(std::move(node)),
conn_state_(ConnectionState::kNotConnected,
node_.CreateString(LowEnergyData::kInspectConnectionStateName, ""),
&ConnectionStateToString),
bond_data_(std::nullopt, node_.CreateBool(LowEnergyData::kInspectBondDataName, false),
[](const std::optional<sm::PairingData>& p) { return p.has_value(); }),
auto_conn_behavior_(AutoConnectBehavior::kAlways),
features_(std::nullopt, node_.CreateString(LowEnergyData::kInspectFeaturesName, ""),
[](const std::optional<hci::LESupportedFeatures> f) {
return f ? fxl::StringPrintf("%#.16lx", f->le_features) : "";
}) {
ZX_DEBUG_ASSERT(peer_);
}
void Peer::LowEnergyData::SetAutoConnectBehaviorForIntentionalDisconnect(void) {
auto_conn_behavior_ = AutoConnectBehavior::kSkipUntilNextConnection;
}
void Peer::LowEnergyData::SetAutoConnectBehaviorForSuccessfulConnection(void) {
auto_conn_behavior_ = AutoConnectBehavior::kAlways;
}
void Peer::LowEnergyData::SetAdvertisingData(int8_t rssi, const ByteBuffer& adv) {
adv_data_buffer_ = DynamicByteBuffer(adv.size());
adv.Copy(&adv_data_buffer_);
ProcessNewAdvertisingData(rssi, adv);
}
void Peer::LowEnergyData::AppendScanResponse(int8_t rssi, const ByteBuffer& scan_response) {
if (scan_response.size() == 0u) {
bt_log(SPEW, "gap-le", "ignored empty scan response");
return;
}
DynamicByteBuffer buffer(adv_data_buffer_.size() + scan_response.size());
buffer.Write(adv_data_buffer_);
buffer.Write(scan_response, adv_data_buffer_.size());
adv_data_buffer_ = std::move(buffer);
ProcessNewAdvertisingData(rssi, scan_response);
}
void Peer::LowEnergyData::ProcessNewAdvertisingData(int8_t rssi, const ByteBuffer& new_data) {
// Prolong this peer's expiration in case it is temporary.
peer_->UpdateExpiry();
bool notify_listeners = peer_->SetRssiInternal(rssi);
// Walk through the advertising data and update common fields.
// TODO(armansito): Validate that the advertising data is not malformed?
SupplementDataReader reader(new_data);
DataType type;
BufferView data;
while (reader.GetNextField(&type, &data)) {
if (type == DataType::kCompleteLocalName || type == DataType::kShortenedLocalName) {
// TODO(armansito): Parse more advertising data fields, such as preferred
// connection parameters.
// TODO(NET-607): SetName should be a no-op if a name was obtained via
// the name discovery procedure.
if (peer_->SetNameInternal(data.ToString())) {
notify_listeners = true;
}
}
}
if (notify_listeners) {
peer_->UpdateExpiry();
peer_->NotifyListeners();
}
}
void Peer::LowEnergyData::SetConnectionState(ConnectionState state) {
ZX_DEBUG_ASSERT(peer_->connectable() || state == ConnectionState::kNotConnected);
if (state == connection_state()) {
bt_log(TRACE, "gap-le", "LE connection state already \"%s\"!",
ConnectionStateToString(state).c_str());
return;
}
bt_log(TRACE, "gap-le", "peer (%s) LE connection state changed from \"%s\" to \"%s\"",
bt_str(peer_->identifier()), ConnectionStateToString(connection_state()).c_str(),
ConnectionStateToString(state).c_str());
conn_state_.Set(state);
// Become non-temporary if connected or a connection attempt is in progress.
// Otherwise, become temporary again if the identity is unknown.
if (state == ConnectionState::kInitializing || state == ConnectionState::kConnected) {
peer_->TryMakeNonTemporary();
} else if (state == ConnectionState::kNotConnected && !peer_->identity_known()) {
bt_log(TRACE, "gap", "became temporary: %s:", bt_str(*peer_));
peer_->temporary_.Set(true);
}
peer_->UpdateExpiry();
peer_->NotifyListeners();
}
void Peer::LowEnergyData::SetConnectionParameters(const hci::LEConnectionParameters& params) {
ZX_DEBUG_ASSERT(peer_->connectable());
conn_params_ = params;
}
void Peer::LowEnergyData::SetPreferredConnectionParameters(
const hci::LEPreferredConnectionParameters& params) {
ZX_DEBUG_ASSERT(peer_->connectable());
preferred_conn_params_ = params;
}
void Peer::LowEnergyData::SetBondData(const sm::PairingData& bond_data) {
ZX_DEBUG_ASSERT(peer_->connectable());
ZX_DEBUG_ASSERT(peer_->address().type() != DeviceAddress::Type::kLEAnonymous);
// Make sure the peer is non-temporary.
peer_->TryMakeNonTemporary();
// This will mark the peer as bonded
bond_data_.Set(bond_data);
// Update to the new identity address if the current address is random.
if (peer_->address().type() == DeviceAddress::Type::kLERandom && bond_data.identity_address) {
peer_->set_identity_known(true);
peer_->set_address(*bond_data.identity_address);
}
peer_->NotifyListeners();
}
void Peer::LowEnergyData::ClearBondData() {
ZX_ASSERT(bond_data_->has_value());
if (bond_data_->value().irk) {
peer_->set_identity_known(false);
}
bond_data_.Set(std::nullopt);
}
Peer::BrEdrData::BrEdrData(Peer* owner, inspect::Node node)
: peer_(owner),
node_(std::move(node)),
conn_state_(ConnectionState::kNotConnected,
node_.CreateString(BrEdrData::kInspectConnectionStateName, ""),
&ConnectionStateToString),
eir_len_(0u),
link_key_(std::nullopt, node_.CreateBool(BrEdrData::kInspectLinkKeyName, false),
[](const std::optional<sm::LTK>& l) { return l.has_value(); }) {
ZX_DEBUG_ASSERT(peer_);
ZX_DEBUG_ASSERT(peer_->identity_known());
// Devices that are capable of BR/EDR and use a LE random device address will
// end up with separate entries for the BR/EDR and LE addresses.
ZX_DEBUG_ASSERT(peer_->address().type() != DeviceAddress::Type::kLERandom &&
peer_->address().type() != DeviceAddress::Type::kLEAnonymous);
address_ = {DeviceAddress::Type::kBREDR, peer_->address().value()};
}
void Peer::BrEdrData::SetInquiryData(const hci::InquiryResult& value) {
ZX_DEBUG_ASSERT(peer_->address().value() == value.bd_addr);
SetInquiryData(value.class_of_device, value.clock_offset, value.page_scan_repetition_mode);
}
void Peer::BrEdrData::SetInquiryData(const hci::InquiryResultRSSI& value) {
ZX_DEBUG_ASSERT(peer_->address().value() == value.bd_addr);
SetInquiryData(value.class_of_device, value.clock_offset, value.page_scan_repetition_mode,
value.rssi);
}
void Peer::BrEdrData::SetInquiryData(const hci::ExtendedInquiryResultEventParams& value) {
ZX_DEBUG_ASSERT(peer_->address().value() == value.bd_addr);
SetInquiryData(
value.class_of_device, value.clock_offset, value.page_scan_repetition_mode, value.rssi,
BufferView(value.extended_inquiry_response, sizeof(value.extended_inquiry_response)));
}
void Peer::BrEdrData::SetConnectionState(ConnectionState state) {
ZX_DEBUG_ASSERT(peer_->connectable() || state == ConnectionState::kNotConnected);
if (state == connection_state()) {
bt_log(TRACE, "gap-bredr", "BR/EDR connection state already \"%s\"",
ConnectionStateToString(state).c_str());
return;
}
bt_log(TRACE, "gap-bredr", "peer (%s) BR/EDR connection state changed from \"%s\" to \"%s\"",
bt_str(peer_->identifier()), ConnectionStateToString(connection_state()).c_str(),
ConnectionStateToString(state).c_str());
conn_state_.Set(state);
peer_->UpdateExpiry();
peer_->NotifyListeners();
// Become non-temporary if we became connected. BR/EDR device remain
// non-temporary afterwards.
if (state == ConnectionState::kConnected) {
peer_->TryMakeNonTemporary();
}
}
void Peer::BrEdrData::SetInquiryData(DeviceClass device_class, uint16_t clock_offset,
hci::PageScanRepetitionMode page_scan_rep_mode, int8_t rssi,
const BufferView& eir_data) {
peer_->UpdateExpiry();
bool notify_listeners = false;
// TODO(armansito): Consider sending notifications for RSSI updates perhaps
// with throttling to avoid spamming.
peer_->SetRssiInternal(rssi);
page_scan_rep_mode_ = page_scan_rep_mode;
clock_offset_ = static_cast<uint16_t>(hci::kClockOffsetValidFlagBit | le16toh(clock_offset));
if (!device_class_ || *device_class_ != device_class) {
device_class_ = device_class;
notify_listeners = true;
}
if (eir_data.size() && SetEirData(eir_data)) {
notify_listeners = true;
}
if (notify_listeners) {
peer_->NotifyListeners();
}
}
bool Peer::BrEdrData::SetEirData(const ByteBuffer& eir) {
ZX_DEBUG_ASSERT(eir.size());
// TODO(armansito): Validate that the EIR data is not malformed?
if (eir_buffer_.size() < eir.size()) {
eir_buffer_ = DynamicByteBuffer(eir.size());
}
eir_len_ = eir.size();
eir.Copy(&eir_buffer_);
SupplementDataReader reader(eir);
DataType type;
BufferView data;
bool changed = false;
while (reader.GetNextField(&type, &data)) {
if (type == DataType::kCompleteLocalName) {
// TODO(armansito): Parse more fields.
// TODO(armansito): SetName should be a no-op if a name was obtained via
// the name discovery procedure.
changed = peer_->SetNameInternal(data.ToString());
}
}
return changed;
}
void Peer::BrEdrData::SetBondData(const sm::LTK& link_key) {
ZX_DEBUG_ASSERT(peer_->connectable());
// Make sure the peer is non-temporary.
peer_->TryMakeNonTemporary();
// Storing the key establishes the bond.
link_key_.Set(link_key);
peer_->NotifyListeners();
}
void Peer::BrEdrData::ClearBondData() {
ZX_ASSERT(link_key_->has_value());
link_key_.Set(std::nullopt);
}
Peer::Peer(DeviceCallback notify_listeners_callback, DeviceCallback update_expiry_callback,
DeviceCallback dual_mode_callback, PeerId identifier, const DeviceAddress& address,
bool connectable, inspect::Node node)
: node_(std::move(node)),
notify_listeners_callback_(std::move(notify_listeners_callback)),
update_expiry_callback_(std::move(update_expiry_callback)),
dual_mode_callback_(std::move(dual_mode_callback)),
identifier_(identifier, node_.CreateString(Peer::kInspectPeerIdName, "")),
technology_((address.type() == DeviceAddress::Type::kBREDR) ? TechnologyType::kClassic
: TechnologyType::kLowEnergy,
node_.CreateString(Peer::kInspectTechnologyName, ""),
[](TechnologyType t) { return TechnologyTypeToString(t); }),
address_(address, node_.CreateString(Peer::kInspectAddressName, "")),
identity_known_(false),
lmp_version_(std::nullopt, node_.CreateString(Peer::kInspectVersionName, ""),
[](const std::optional<hci::HCIVersion>& v) {
return v ? hci::HCIVersionToString(*v) : "";
}),
lmp_manufacturer_(
std::nullopt, node_.CreateString(Peer::kInspectManufacturerName, ""),
[](const std::optional<uint16_t>& m) { return m ? GetManufacturerName(*m) : ""; }),
lmp_features_(hci::LMPFeatureSet(), node_.CreateString(Peer::kInspectFeaturesName, "")),
connectable_(connectable, node_.CreateBool(Peer::kInspectConnectableName, "")),
temporary_(true, node_.CreateBool(Peer::kInspectTemporaryName, true)),
rssi_(hci::kRSSIInvalid) {
ZX_DEBUG_ASSERT(notify_listeners_callback_);
ZX_DEBUG_ASSERT(update_expiry_callback_);
ZX_DEBUG_ASSERT(dual_mode_callback_);
ZX_DEBUG_ASSERT(identifier.IsValid());
if (address.type() == DeviceAddress::Type::kBREDR ||
address.type() == DeviceAddress::Type::kLEPublic) {
identity_known_ = true;
}
// Initialize transport-specific state.
if (*technology_ == TechnologyType::kClassic) {
bredr_data_ = BrEdrData(this, node_.CreateChild(Peer::BrEdrData::kInspectNodeName));
} else {
le_data_ = LowEnergyData(this, node_.CreateChild(Peer::LowEnergyData::kInspectNodeName));
}
}
Peer::LowEnergyData& Peer::MutLe() {
if (le_data_) {
return *le_data_;
}
le_data_ = LowEnergyData(this, node_.CreateChild(Peer::LowEnergyData::kInspectNodeName));
// Make dual-mode if both transport states have been initialized.
if (bredr_data_) {
MakeDualMode();
}
return *le_data_;
}
Peer::BrEdrData& Peer::MutBrEdr() {
if (bredr_data_) {
return *bredr_data_;
}
bredr_data_ = BrEdrData(this, node_.CreateChild(Peer::BrEdrData::kInspectNodeName));
// Make dual-mode if both transport states have been initialized.
if (le_data_) {
MakeDualMode();
}
return *bredr_data_;
}
std::string Peer::ToString() const {
return fxl::StringPrintf("{peer id: %s, address: %s}", bt_str(*identifier_), bt_str(*address_));
}
void Peer::SetName(const std::string& name) {
if (SetNameInternal(name)) {
UpdateExpiry();
NotifyListeners();
}
}
// Private methods below:
bool Peer::SetRssiInternal(int8_t rssi) {
if (rssi != hci::kRSSIInvalid && rssi_ != rssi) {
rssi_ = rssi;
return true;
}
return false;
}
bool Peer::SetNameInternal(const std::string& name) {
if (!name_ || *name_ != name) {
name_ = name;
return true;
}
return false;
}
bool Peer::TryMakeNonTemporary() {
// TODO(armansito): Since we don't currently support address resolution,
// random addresses should never be persisted.
if (!connectable()) {
bt_log(TRACE, "gap", "remains temporary: %s", bt_str(*this));
return false;
}
bt_log(TRACE, "gap", "became non-temporary: %s:", bt_str(*this));
if (*temporary_) {
temporary_.Set(false);
UpdateExpiry();
NotifyListeners();
}
return true;
}
void Peer::UpdateExpiry() {
ZX_DEBUG_ASSERT(update_expiry_callback_);
update_expiry_callback_(*this);
}
void Peer::NotifyListeners() {
ZX_DEBUG_ASSERT(notify_listeners_callback_);
notify_listeners_callback_(*this);
}
void Peer::MakeDualMode() {
technology_.Set(TechnologyType::kDualMode);
ZX_DEBUG_ASSERT(dual_mode_callback_);
dual_mode_callback_(*this);
}
} // namespace gap
} // namespace bt