subsurface/core/qt-ble.cpp
Dirk Hohndel 300248f446 Qt6: use the newer createCentral() API
This will cause us problems when using Qt6 on Android - but I don't see
this happening any time soon.

Signed-off-by: Dirk Hohndel <dirk@hohndel.org>
2022-03-12 08:28:32 -08:00

746 lines
24 KiB
C++

// SPDX-License-Identifier: GPL-2.0
#include <errno.h>
#include <QtBluetooth/QBluetoothAddress>
#include <QLowEnergyController>
#include <QLowEnergyService>
#include <QCoreApplication>
#include <QElapsedTimer>
#include <QEventLoop>
#include <QThread>
#include <QTimer>
#include <QTime>
#include <QDebug>
#include <QLoggingCategory>
#include <libdivecomputer/version.h>
#include <libdivecomputer/ble.h>
#include "libdivecomputer.h"
#include "core/qt-ble.h"
#include "core/btdiscovery.h"
#include "core/errorhelper.h"
#include "core/subsurface-string.h"
#define BLE_TIMEOUT 12000 // 12 seconds seems like a very long time to wait
#define DEBUG_THRESHOLD 50
static int debugCounter;
#define IS_HW(_d) same_string((_d)->vendor, "Heinrichs Weikamp")
#define IS_SHEARWATER(_d) same_string((_d)->vendor, "Shearwater")
#define IS_GARMIN(_d) same_string((_d)->vendor, "Garmin")
#define MAXIMAL_HW_CREDIT 254
#define MINIMAL_HW_CREDIT 32
#define WAITFOR(expression, ms) do { \
Q_ASSERT(QCoreApplication::instance()); \
Q_ASSERT(QThread::currentThread()); \
\
if (expression) \
break; \
QElapsedTimer timer; \
timer.start(); \
\
do { \
QCoreApplication::processEvents(QEventLoop::AllEvents, ms); \
if (expression) \
break; \
QThread::msleep(10); \
} while (timer.elapsed() < (ms)); \
} while (0)
extern "C" {
void BLEObject::serviceStateChanged(QLowEnergyService::ServiceState newState)
{
if (verbose > 2 || debugCounter < DEBUG_THRESHOLD)
qDebug() << "serviceStateChanged";
auto service = qobject_cast<QLowEnergyService*>(sender());
if (service)
if (verbose > 2 || debugCounter < DEBUG_THRESHOLD)
qDebug() << service->serviceUuid() << newState;
}
void BLEObject::characteristcStateChanged(const QLowEnergyCharacteristic &c, const QByteArray &value)
{
if (verbose > 2 || debugCounter < DEBUG_THRESHOLD)
qDebug() << QTime::currentTime() << "packet RECV" << value.toHex();
if (IS_HW(device)) {
if (c.uuid() == telit[TELIT_DATA_TX] || c.uuid() == ublox[UBLOX_DATA_TX]) {
hw_credit--;
receivedPackets.append(value);
if (hw_credit == MINIMAL_HW_CREDIT)
setHwCredit(MAXIMAL_HW_CREDIT - MINIMAL_HW_CREDIT);
} else {
qDebug() << "ignore packet from" << c.uuid() << value.toHex();
}
} else {
receivedPackets.append(value);
}
}
void BLEObject::characteristicWritten(const QLowEnergyCharacteristic &c, const QByteArray &value)
{
if (IS_HW(device)) {
if (c.uuid() == telit[TELIT_CREDITS_RX] || c.uuid() == ublox[UBLOX_CREDITS_RX]) {
bool ok;
hw_credit += value.toHex().toInt(&ok, 16);
isCharacteristicWritten = true;
}
} else {
if (verbose > 2 || debugCounter < DEBUG_THRESHOLD)
qDebug() << "BLEObject::characteristicWritten";
}
}
void BLEObject::writeCompleted(const QLowEnergyDescriptor&, const QByteArray&)
{
if (verbose > 2 || debugCounter < DEBUG_THRESHOLD)
qDebug() << "BLE write completed";
desc_written++;
}
struct uuid_match {
const char *uuid, *details;
};
static const char *match_uuid_list(const QBluetoothUuid &match, const struct uuid_match *array)
{
const char *uuid;
while ((uuid = array->uuid) != NULL) {
if (match == QBluetoothUuid(QUuid(uuid)))
return array->details;
array++;
}
return NULL;
}
//
// Known BLE GATT service UUID's that we should prefer for the serial
// emulation.
//
// The Bluetooth SIG is a disgrace, and never standardized any serial
// communication over BLE. They should just have specified a standard
// UUID for serial service, but preferred their idiotic model of
// "vendor specific" garbage instead. So everybody has made their own
// serial protocol over BLE GATT, which all look fairly similar, but
// with pointless and stupid differences just because the BLE SIG
// couldn't be arsed to do their job properly.
//
// Am I bitter? Just a bit. I know that "standards bodies" is just a
// fancy way of saying "incompetent tech politics", but still.. It's
// not like legacy BT didn't have a standard serial encapsulation.
// Oh. It did, didn't it?
//
static const struct uuid_match serial_service_uuids[] = {
{ "0000fefb-0000-1000-8000-00805f9b34fb", "Heinrichs-Weikamp (Telit/Stollmann)" },
{ "2456e1b9-26e2-8f83-e744-f34f01e9d701", "Heinrichs-Weikamp (U-Blox)" },
{ "544e326b-5b72-c6b0-1c46-41c1bc448118", "Mares BlueLink Pro" },
{ "6e400001-b5a3-f393-e0a9-e50e24dcca9e", "Nordic Semi UART" },
{ "98ae7120-e62e-11e3-badd-0002a5d5c51b", "Suunto (EON Steel/Core, G5)" },
{ "cb3c4555-d670-4670-bc20-b61dbc851e9a", "Pelagic (i770R, i200C, Pro Plus X, Geo 4.0)" },
{ "fdcdeaaa-295d-470e-bf15-04217b7aa0a0", "ScubaPro G2"},
{ "fe25c237-0ece-443c-b0aa-e02033e7029d", "Shearwater (Perdix/Teric/Peregrine)" },
{ NULL, }
};
//
// Sometimes we don't know which is the good service, but we can tell
// that a service is NOT a serial service because we've seen that
// people use it for firmware upgrades.
//
static const struct uuid_match upgrade_service_uuids[] = {
{ "00001530-1212-efde-1523-785feabcd123", "Nordic Upgrade" },
{ "9e5d1e47-5c13-43a0-8635-82ad38a1386f", "Broadcom Upgrade #1" },
{ "a86abc2d-d44c-442e-99f7-80059a873e36", "Broadcom Upgrade #2" },
{ NULL, }
};
static const char *is_known_serial_service(const QBluetoothUuid &service)
{
return match_uuid_list(service, serial_service_uuids);
}
static const char *is_known_bad_service(const QBluetoothUuid &service)
{
return match_uuid_list(service, upgrade_service_uuids);
}
void BLEObject::addService(const QBluetoothUuid &newService)
{
const char *details;
qDebug() << "Found service" << newService;
//
// Known bad service that we should ignore?
// (typically firmware update service).
//
details = is_known_bad_service(newService);
if (details) {
qDebug () << " .. ignoring service" << details;
return;
}
//
// If it's a known serial service, clear any other previous
// services we've found - we'll use this one.
//
// Note that if it's not _known_ to be good, we'll ignore
// any standard services. They are usually things like battery
// status or device name services.
//
// But Heinrich-Weicamp actually has a standard service ID in the
// known good category, because Telit/Stollmann (the manufacturer)
// applied for a UUID for its product.
//
// If it's not a known service, and not a standard one, we'll just
// add it to the list and then we'll try our heuristics on that
// list.
//
details = is_known_serial_service(newService);
if (details) {
qDebug () << " .. recognized service" << details;
services.clear();
} else {
bool isStandardUuid = false;
newService.toUInt16(&isStandardUuid);
if (isStandardUuid) {
qDebug () << " .. ignoring standard service";
return;
}
}
auto service = controller->createServiceObject(newService, this);
if (service) {
// provide some visibility into what's happening in the log
service->connect(service, &QLowEnergyService::stateChanged,[=](QLowEnergyService::ServiceState newState) {
qDebug() << " .. service state changed to" << newState;
});
#if QT_VERSION >= QT_VERSION_CHECK(6, 0, 0)
service->connect(service, &QLowEnergyService::errorOccurred,
#else
service->connect(service, QOverload<QLowEnergyService::ServiceError>::of(&QLowEnergyService::error),
#endif
[=](QLowEnergyService::ServiceError newError) {
qDebug() << "error discovering service details" << newError;
});
services.append(service);
qDebug() << "starting service characteristics discovery";
service->discoverDetails();
}
}
BLEObject::BLEObject(QLowEnergyController *c, device_data_t *d)
{
controller = c;
device = d;
debugCounter = 0;
isCharacteristicWritten = false;
timeout = BLE_TIMEOUT;
}
BLEObject::~BLEObject()
{
qDebug() << "Deleting BLE object";
qDeleteAll(services);
delete controller;
}
/*
* The McLean Extreme has just one vendor service, but then inside that
* service it has several characteristics, and it's not obvious which
* ones are the read/write ones.
*
* So just make sure to skip the ones we don't want.
*
* The proper ones are:
*
* Microchip service UUID: 49535343-fe7d-4ae5-8fa9-9fafd205e455
* TX characteristic: 49535343-1e4d-4bd9-ba61-23c647249616
* RX characteristic: 49535343-8841-43f4-a8d4-ecbe34729bb3
*/
static const struct uuid_match skip_characteristics[] = {
{ "49535343-6daa-4d02-abf6-19569aca69fe", "McLean Extreme Avoid" },
{ "49535343-aca3-481c-91ec-d85e28a60318", "McLean Extreme Avoid" },
{ "49535343-026e-3a9b-954c-97daef17e26e", "McLean Extreme Avoid" },
{ "49535343-4c8a-39b3-2f49-511cff073b7e", "McLean Extreme Avoid" },
{ NULL, }
};
// a write characteristic needs Write or WriteNoResponse
static bool is_write_characteristic(const QLowEnergyCharacteristic &c)
{
if (match_uuid_list(c.uuid(), skip_characteristics))
return false;
return c.properties() &
(QLowEnergyCharacteristic::Write |
QLowEnergyCharacteristic::WriteNoResponse);
}
// We need a Notify or Indicate for the reading side, and
// a descriptor to enable it
static bool is_read_characteristic(const QLowEnergyCharacteristic &c)
{
if (match_uuid_list(c.uuid(), skip_characteristics))
return false;
return !c.descriptors().empty() &&
(c.properties() &
(QLowEnergyCharacteristic::Notify |
QLowEnergyCharacteristic::Indicate));
}
dc_status_t BLEObject::write(const void *data, size_t size, size_t *actual)
{
if (actual) *actual = 0;
if (!receivedPackets.isEmpty()) {
qDebug() << ".. write HIT with still incoming packets in queue";
do {
receivedPackets.takeFirst();
} while (!receivedPackets.isEmpty());
}
foreach (const QLowEnergyCharacteristic &c, preferredService()->characteristics()) {
if (!is_write_characteristic(c))
continue;
QByteArray bytes((const char *)data, (int) size);
if (verbose > 2 || debugCounter < DEBUG_THRESHOLD)
qDebug() << QTime::currentTime() << "packet SEND" << bytes.toHex();
QLowEnergyService::WriteMode mode;
mode = (c.properties() & QLowEnergyCharacteristic::WriteNoResponse) ?
QLowEnergyService::WriteWithoutResponse :
QLowEnergyService::WriteWithResponse;
preferredService()->writeCharacteristic(c, bytes, mode);
if (actual) *actual = size;
return DC_STATUS_SUCCESS;
}
return DC_STATUS_IO;
}
dc_status_t BLEObject::poll(int timeout)
{
if (receivedPackets.isEmpty()) {
QList<QLowEnergyCharacteristic> list = preferredService()->characteristics();
if (list.isEmpty())
return DC_STATUS_IO;
if (verbose > 2 || debugCounter < DEBUG_THRESHOLD)
qDebug() << QTime::currentTime() << "packet WAIT";
WAITFOR(!receivedPackets.isEmpty(), timeout);
if (receivedPackets.isEmpty())
return DC_STATUS_TIMEOUT;
}
return DC_STATUS_SUCCESS;
}
dc_status_t BLEObject::read(void *data, size_t size, size_t *actual)
{
dc_status_t rc;
if (actual)
*actual = 0;
// Wait for a packet
rc = poll(timeout);
if (rc != DC_STATUS_SUCCESS)
return rc;
QByteArray packet = receivedPackets.takeFirst();
// Did we get more than asked for?
//
// Put back the left-over at the beginning of the
// received packet list, and truncate the packet
// we got to just the part asked for.
if ((size_t)packet.size() > size) {
receivedPackets.prepend(packet.mid(size));
packet.truncate(size);
}
memcpy((char *)data, packet.data(), packet.size());
if (actual)
*actual += packet.size();
if (verbose > 2 || debugCounter < DEBUG_THRESHOLD)
qDebug() << QTime::currentTime() << "packet READ" << packet.toHex();
return DC_STATUS_SUCCESS;
}
//
// select_preferred_service() gets called after all services
// have been discovered, and the discovery process has been
// started (by addService(), which calls service->discoverDetails())
//
// The role of this function is to wait for all service
// discovery to finish, and pick the preferred service.
//
// NOTE! Picking the preferred service is divecomputer-specific.
// Right now we special-case the HW known service number, but for
// others we just pick the first one that isn't a standard service.
//
// That's wrong, but works for the simple case.
//
dc_status_t BLEObject::select_preferred_service(void)
{
// Wait for each service to finish discovering
foreach (const QLowEnergyService *s, services) {
#if QT_VERSION >= QT_VERSION_CHECK(6, 0, 0)
WAITFOR(s->state() != QLowEnergyService::RemoteServiceDiscovering, BLE_TIMEOUT);
if (s->state() == QLowEnergyService::RemoteServiceDiscovering)
#else
WAITFOR(s->state() != QLowEnergyService::DiscoveringServices, BLE_TIMEOUT);
if (s->state() == QLowEnergyService::DiscoveringServices)
#endif
qDebug() << " .. service " << s->serviceUuid() << "still hasn't completed discovery - trouble ahead";
}
// Print out the services for debugging
foreach (const QLowEnergyService *s, services) {
qDebug() << "Found service" << s->serviceUuid() << s->serviceName();
foreach (const QLowEnergyCharacteristic &c, s->characteristics()) {
qDebug() << " c:" << c.uuid();
foreach (const QLowEnergyDescriptor &d, c.descriptors())
qDebug() << " d:" << d.uuid();
}
}
// Pick the preferred one
foreach (QLowEnergyService *s, services) {
#if QT_VERSION >= QT_VERSION_CHECK(6, 0, 0)
if (s->state() != QLowEnergyService::RemoteServiceDiscovered)
#else
if (s->state() != QLowEnergyService::ServiceDiscovered)
#endif
continue;
bool hasread = false;
bool haswrite = false;
QBluetoothUuid uuid = s->serviceUuid();
foreach (const QLowEnergyCharacteristic &c, s->characteristics()) {
hasread |= is_read_characteristic(c);
haswrite |= is_write_characteristic(c);
}
if (!hasread) {
qDebug () << " .. ignoring service without read characteristic" << uuid;
continue;
}
if (!haswrite) {
qDebug () << " .. ignoring service without write characteristic" << uuid;
continue;
}
// We now know that the service has both read and write characteristics
preferred = s;
qDebug() << "Using service" << s->serviceUuid() << "as preferred service";
break;
}
if (!preferred) {
qDebug() << "failed to find suitable service";
report_error("Failed to find suitable BLE GATT service");
return DC_STATUS_IO;
}
connect(preferred, &QLowEnergyService::stateChanged, this, &BLEObject::serviceStateChanged);
connect(preferred, &QLowEnergyService::characteristicChanged, this, &BLEObject::characteristcStateChanged);
connect(preferred, &QLowEnergyService::characteristicWritten, this, &BLEObject::characteristicWritten);
connect(preferred, &QLowEnergyService::descriptorWritten, this, &BLEObject::writeCompleted);
return DC_STATUS_SUCCESS;
}
dc_status_t BLEObject::setHwCredit(unsigned int c)
{
/* The Terminal I/O client transmits initial UART credits to the server (see 6.5).
*
* Notice that we have to write to the characteristic here, and not to its
* descriptor as for the enabeling of notifications or indications.
*
* Futher notice that this function has the implicit effect of processing the
* event loop (due to waiting for the confirmation of the credit request).
* So, as characteristcStateChanged will be triggered, while receiving
* data from the OSTC, these are processed too.
*/
QList<QLowEnergyCharacteristic> list = preferredService()->characteristics();
int credits_rx = list.length() == 4 ? TELIT_CREDITS_RX : UBLOX_CREDITS_RX;
isCharacteristicWritten = false;
preferredService()->writeCharacteristic(list[credits_rx],
QByteArray(1, c),
QLowEnergyService::WriteWithResponse);
/* And wait for the answer*/
WAITFOR(isCharacteristicWritten, BLE_TIMEOUT);
if (!isCharacteristicWritten)
return DC_STATUS_TIMEOUT;
return DC_STATUS_SUCCESS;
}
dc_status_t BLEObject::setupHwTerminalIo(const QList<QLowEnergyCharacteristic> &allC)
{ /* This initalizes the Terminal I/O client as described in
* http://www.telit.com/fileadmin/user_upload/products/Downloads/sr-rf/BlueMod/TIO_Implementation_Guide_r04.pdf
* Referenced section numbers below are from that document.
*
* This is for all HW computers, that use referenced BT/BLE hardware module from Telit
* (formerly Stollmann). The 16 bit UUID 0xFEFB (or a derived 128 bit UUID starting with
* 0x0000FEFB is a clear indication that the OSTC is equipped with this BT/BLE hardware.
*/
if (allC.length() != 4 && allC.length() != 2) {
qDebug() << "This should not happen. HW/OSTC BT/BLE device without 2(UBLOX) or 4(TELIT) Characteristics";
return DC_STATUS_IO;
}
/* The Terminal I/O client subscribes to indications of the UART credits TX
* characteristic (see 6.4).
*
* Notice that indications are subscribed to by writing 0x0200 to its descriptor. This
* can be understood by looking for Client Characteristic Configuration, Assigned
* Number: 0x2902. Enabling/Disabeling is setting the proper bit, and they
* differ for indications and notifications.
*/
int credits_tx = allC.length() == 4 ? TELIT_CREDITS_TX : UBLOX_CREDITS_TX;
QLowEnergyDescriptor d = allC[credits_tx].descriptors().first();
preferredService()->writeDescriptor(d, QByteArray::fromHex("0200"));
/* The Terminal I/O client subscribes to notifications of the UART data TX
* characteristic (see 6.2).
*/
int data_tx = allC.length() == 4 ? TELIT_DATA_TX : UBLOX_DATA_TX;
d = allC[data_tx].descriptors().first();
preferredService()->writeDescriptor(d, QByteArray::fromHex("0100"));
/* The Terminal I/O client transmits initial UART credits to the server (see 6.5). */
return setHwCredit(MAXIMAL_HW_CREDIT);
}
#if !defined(Q_OS_WIN)
// Bluez is broken, and doesn't have a sane way to query
// whether to use a random address or not. So we have to
// fake it.
static int use_random_address(device_data_t *user_device)
{
return IS_SHEARWATER(user_device) || IS_GARMIN(user_device);
}
#endif
dc_status_t qt_ble_open(void **io, dc_context_t *, const char *devaddr, device_data_t *user_device)
{
debugCounter = 0;
QLoggingCategory::setFilterRules(QStringLiteral("qt.bluetooth* = true"));
/*
* LE-only devices get the "LE:" prepended by the scanning
* code, so that the rfcomm code can see they only do LE.
*
* We just skip that prefix (and it doesn't always exist,
* since the device may support both legacy BT and LE).
*/
if (!strncmp(devaddr, "LE:", 3))
devaddr += 3;
// HACK ALERT! Qt 5.9 needs this for proper Bluez operation
qputenv("QT_DEFAULT_CENTRAL_SERVICES", "1");
#if defined(Q_OS_MACOS) || defined(Q_OS_IOS) || QT_VERSION >= QT_VERSION_CHECK(6, 0, 0)
QBluetoothDeviceInfo remoteDevice = getBtDeviceInfo(QString(devaddr));
QLowEnergyController *controller = QLowEnergyController::createCentral(remoteDevice);
#else
// this is deprecated but given that we don't use Qt to scan for
// devices on Android, we don't have QBluetoothDeviceInfo for the
// paired devices and therefore cannot use the newer interfaces
// that are preferred starting with Qt 5.7
QBluetoothAddress remoteDeviceAddress(devaddr);
QLowEnergyController *controller = new QLowEnergyController(remoteDeviceAddress);
#endif
qDebug() << "qt_ble_open(" << devaddr << ")";
#if !defined(Q_OS_WIN)
if (use_random_address(user_device))
controller->setRemoteAddressType(QLowEnergyController::RandomAddress);
#endif
// Try to connect to the device
controller->connectToDevice();
// Create a timer. If the connection doesn't succeed after five seconds or no error occurs then stop the opening step
WAITFOR(controller->state() != QLowEnergyController::ConnectingState, BLE_TIMEOUT);
switch (controller->state()) {
case QLowEnergyController::ConnectedState:
qDebug() << "connected to the controller for device" << devaddr;
break;
case QLowEnergyController::ConnectingState:
qDebug() << "timeout while trying to connect to the controller " << devaddr;
report_error("Timeout while trying to connect to %s", devaddr);
delete controller;
return DC_STATUS_IO;
default:
qDebug() << "failed to connect to the controller " << devaddr << "with error" << controller->errorString();
report_error("Failed to connect to %s: '%s'", devaddr, qPrintable(controller->errorString()));
delete controller;
return DC_STATUS_IO;
}
// We need to discover services etc here!
// Note that ble takes ownership of controller and henceforth deleting ble will
// take care of deleting controller.
BLEObject *ble = new BLEObject(controller, user_device);
// we used to call our addService function the moment a service was discovered, but that
// could cause us to try to discover the details of a characteristic while we were still serching
// for services, which can cause a failure in the Qt BLE stack.
// While that actual error was likely caused by a bug in BLE implementation of a dive computer,
// the underlying issue still seems worth addressing.
// Finish discovering the services, then add all those services and discover their characteristics.
ble->connect(controller, &QLowEnergyController::discoveryFinished, [=] {
qDebug() << "finished service discovery, start discovering characteristics";
foreach(QBluetoothUuid s, controller->services()) {
ble->addService(s);
}
});
#if QT_VERSION >= QT_VERSION_CHECK(6, 0, 0)
ble->connect(controller, &QLowEnergyController::errorOccurred, [=](QLowEnergyController::Error newError) {
#else
ble->connect(controller, QOverload<QLowEnergyController::Error>::of(&QLowEnergyController::error), [=](QLowEnergyController::Error newError) {
#endif
qDebug() << "controler discovery error" << controller->errorString() << newError;
});
controller->discoverServices();
WAITFOR(controller->state() != QLowEnergyController::DiscoveringState, BLE_TIMEOUT);
if (controller->state() == QLowEnergyController::DiscoveringState)
qDebug() << " .. even after waiting for the full BLE timeout, controller is still in discovering state";
qDebug() << " .. done discovering services";
dc_status_t error = ble->select_preferred_service();
if (error != DC_STATUS_SUCCESS) {
qDebug() << "failed to find suitable service on" << devaddr;
report_error("Failed to find suitable service on '%s'", devaddr);
delete ble;
return error;
}
qDebug() << " .. enabling notifications";
/* Enable notifications */
QList<QLowEnergyCharacteristic> list = ble->preferredService()->characteristics();
if (IS_HW(user_device)) {
dc_status_t r = ble->setupHwTerminalIo(list);
if (r != DC_STATUS_SUCCESS) {
delete ble;
return r;
}
} else {
for (const QLowEnergyCharacteristic &c: list) {
if (!is_read_characteristic(c))
continue;
qDebug() << "Using read characteristic" << c.uuid();
const QList<QLowEnergyDescriptor> l = c.descriptors();
QLowEnergyDescriptor d = l.first();
for (const QLowEnergyDescriptor &tmp: l) {
if (tmp.type() == QBluetoothUuid::DescriptorType::ClientCharacteristicConfiguration) {
d = tmp;
break;
}
}
qDebug() << "now writing \"0x0100\" to the descriptor" << d.uuid().toString();
ble->preferredService()->writeDescriptor(d, QByteArray::fromHex("0100"));
WAITFOR(ble->descriptorWritten(), 1000);
break;
}
}
// Fill in info
*io = (void *)ble;
return DC_STATUS_SUCCESS;
}
dc_status_t qt_ble_close(void *io)
{
BLEObject *ble = (BLEObject *) io;
delete ble;
return DC_STATUS_SUCCESS;
}
static void checkThreshold()
{
if (++debugCounter == DEBUG_THRESHOLD) {
QLoggingCategory::setFilterRules(QStringLiteral("qt.bluetooth* = false"));
qDebug() << "turning off further BT debug output";
}
}
/*
* NOTE! The 'set_timeout()' function only affects the timeout
* for qt_ble_read(), not for the various general BLE operations.
*/
dc_status_t qt_ble_set_timeout(void *io, int timeout)
{
BLEObject *ble = (BLEObject *) io;
ble->set_timeout(timeout);
return DC_STATUS_SUCCESS;
}
dc_status_t qt_ble_read(void *io, void* data, size_t size, size_t *actual)
{
checkThreshold();
BLEObject *ble = (BLEObject *) io;
return ble->read(data, size, actual);
}
dc_status_t qt_ble_write(void *io, const void* data, size_t size, size_t *actual)
{
checkThreshold();
BLEObject *ble = (BLEObject *) io;
return ble->write(data, size, actual);
}
dc_status_t qt_ble_poll(void *io, int timeout)
{
BLEObject *ble = (BLEObject *) io;
return ble->poll(timeout);
}
dc_status_t qt_ble_ioctl(void *io, unsigned int request, void *data, size_t size)
{
BLEObject *ble = (BLEObject *) io;
switch (request) {
case DC_IOCTL_BLE_GET_NAME:
return ble->get_name((char *) data, size);
default:
return DC_STATUS_UNSUPPORTED;
}
}
} /* extern "C" */