bluetooth/1.0/default/vendor_interface.cc - LeafOS-Project/android_hardware_interfaces - Gitiles

 //
 // Copyright 2016 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.
 //

 #include "vendor_interface.h"

 #include <assert.h>

 #define LOG_TAG "android.hardware.bluetooth@1.0-impl"
 #include <android-base/logging.h>
 #include <cutils/properties.h>
 #include <utils/Log.h>

 #include <dlfcn.h>
 #include <fcntl.h>

 #include "bluetooth_address.h"

 static const char* VENDOR_LIBRARY_NAME = "libbt-vendor.so";
 static const char* VENDOR_LIBRARY_SYMBOL_NAME =
     "BLUETOOTH_VENDOR_LIB_INTERFACE";

 static const int INVALID_FD = -1;

 namespace {

 using android::hardware::bluetooth::V1_0::implementation::VendorInterface;
 using android::hardware::hidl_vec;

 struct {
   tINT_CMD_CBACK cb;
   uint16_t opcode;
 } internal_command;

 // True when LPM is not enabled yet or wake is not asserted.
 bool lpm_wake_deasserted;
 uint32_t lpm_timeout_ms;
 bool recent_activity_flag;

 VendorInterface* g_vendor_interface = nullptr;

 const size_t preamble_size_for_type[] = {
     0, HCI_COMMAND_PREAMBLE_SIZE, HCI_ACL_PREAMBLE_SIZE, HCI_SCO_PREAMBLE_SIZE,
     HCI_EVENT_PREAMBLE_SIZE};
 const size_t packet_length_offset_for_type[] = {
     0, HCI_LENGTH_OFFSET_CMD, HCI_LENGTH_OFFSET_ACL, HCI_LENGTH_OFFSET_SCO,
     HCI_LENGTH_OFFSET_EVT};

 size_t HciGetPacketLengthForType(HciPacketType type, const uint8_t* preamble) {
   size_t offset = packet_length_offset_for_type[type];
   if (type != HCI_PACKET_TYPE_ACL_DATA) return preamble[offset];
   return (((preamble[offset + 1]) << 8) | preamble[offset]);
 }

 HC_BT_HDR* WrapPacketAndCopy(uint16_t event, const hidl_vec<uint8_t>& data) {
   size_t packet_size = data.size() + sizeof(HC_BT_HDR);
   HC_BT_HDR* packet = reinterpret_cast<HC_BT_HDR*>(new uint8_t[packet_size]);
   packet->offset = 0;
   packet->len = data.size();
   packet->layer_specific = 0;
   packet->event = event;
   // TODO(eisenbach): Avoid copy here; if BT_HDR->data can be ensured to
   // be the only way the data is accessed, a pointer could be passed here...
   memcpy(packet->data, data.data(), data.size());
   return packet;
 }

 size_t write_safely(int fd, const uint8_t* data, size_t length) {
   size_t transmitted_length = 0;
   while (length > 0) {
     ssize_t ret =
         TEMP_FAILURE_RETRY(write(fd, data + transmitted_length, length));

     if (ret == -1) {
       if (errno == EAGAIN) continue;
       ALOGE("%s error writing to UART (%s)", __func__, strerror(errno));
       break;

     } else if (ret == 0) {
       // Nothing written :(
       ALOGE("%s zero bytes written - something went wrong...", __func__);
       break;
     }

     transmitted_length += ret;
     length -= ret;
   }

   return transmitted_length;
 }

 bool internal_command_event_match(const hidl_vec<uint8_t>& packet) {
   uint8_t event_code = packet[0];
   if (event_code != HCI_COMMAND_COMPLETE_EVENT) {
     ALOGE("%s: Unhandled event type %02X", __func__, event_code);
     return false;
   }

   size_t opcode_offset = HCI_EVENT_PREAMBLE_SIZE + 1;  // Skip num packets.

   uint16_t opcode = packet[opcode_offset] | (packet[opcode_offset + 1] << 8);

   ALOGV("%s internal_command.opcode = %04X opcode = %04x", __func__,
         internal_command.opcode, opcode);
   return opcode == internal_command.opcode;
 }

 uint8_t transmit_cb(uint16_t opcode, void* buffer, tINT_CMD_CBACK callback) {
   ALOGV("%s opcode: 0x%04x, ptr: %p, cb: %p", __func__, opcode, buffer,
         callback);
   internal_command.cb = callback;
   internal_command.opcode = opcode;
   uint8_t type = HCI_PACKET_TYPE_COMMAND;
   HC_BT_HDR* bt_hdr = reinterpret_cast<HC_BT_HDR*>(buffer);
   VendorInterface::get()->Send(type, bt_hdr->data, bt_hdr->len);
   delete[] reinterpret_cast<uint8_t*>(buffer);
   return true;
 }

 void firmware_config_cb(bt_vendor_op_result_t result) {
   ALOGV("%s result: %d", __func__, result);
   VendorInterface::get()->OnFirmwareConfigured(result);
 }

 void sco_config_cb(bt_vendor_op_result_t result) {
   ALOGD("%s result: %d", __func__, result);
 }

 void low_power_mode_cb(bt_vendor_op_result_t result) {
   ALOGD("%s result: %d", __func__, result);
 }

 void sco_audiostate_cb(bt_vendor_op_result_t result) {
   ALOGD("%s result: %d", __func__, result);
 }

 void* buffer_alloc_cb(int size) {
   void* p = new uint8_t[size];
   ALOGV("%s pts: %p, size: %d", __func__, p, size);
   return p;
 }

 void buffer_free_cb(void* buffer) {
   ALOGV("%s ptr: %p", __func__, buffer);
   delete[] reinterpret_cast<uint8_t*>(buffer);
 }

 void epilog_cb(bt_vendor_op_result_t result) {
   ALOGD("%s result: %d", __func__, result);
 }

 void a2dp_offload_cb(bt_vendor_op_result_t result, bt_vendor_opcode_t op,
                      uint8_t av_handle) {
   ALOGD("%s result: %d, op: %d, handle: %d", __func__, result, op, av_handle);
 }

 const bt_vendor_callbacks_t lib_callbacks = {
     sizeof(lib_callbacks), firmware_config_cb, sco_config_cb,
     low_power_mode_cb,     sco_audiostate_cb,  buffer_alloc_cb,
     buffer_free_cb,        transmit_cb,        epilog_cb,
     a2dp_offload_cb};

 }  // namespace

 namespace android {
 namespace hardware {
 namespace bluetooth {
 namespace V1_0 {
 namespace implementation {

 class FirmwareStartupTimer {
  public:
   FirmwareStartupTimer() : start_time_(std::chrono::steady_clock::now()) {}

   ~FirmwareStartupTimer() {
     std::chrono::duration<double> duration =
         std::chrono::steady_clock::now() - start_time_;
     double s = duration.count();
     if (s == 0) return;
     ALOGI("Firmware configured in %.3fs", s);
   }

  private:
   std::chrono::steady_clock::time_point start_time_;
 };

 bool VendorInterface::Initialize(
     InitializeCompleteCallback initialize_complete_cb,
     PacketReadCallback packet_read_cb) {
   assert(!g_vendor_interface);
   g_vendor_interface = new VendorInterface();
   return g_vendor_interface->Open(initialize_complete_cb, packet_read_cb);
 }

 void VendorInterface::Shutdown() {
   CHECK(g_vendor_interface);
   g_vendor_interface->Close();
   delete g_vendor_interface;
   g_vendor_interface = nullptr;
 }

 VendorInterface* VendorInterface::get() { return g_vendor_interface; }

 bool VendorInterface::Open(InitializeCompleteCallback initialize_complete_cb,
                            PacketReadCallback packet_read_cb) {
   initialize_complete_cb_ = initialize_complete_cb;
   packet_read_cb_ = packet_read_cb;

   // Initialize vendor interface

   lib_handle_ = dlopen(VENDOR_LIBRARY_NAME, RTLD_NOW);
   if (!lib_handle_) {
     ALOGE("%s unable to open %s (%s)", __func__, VENDOR_LIBRARY_NAME,
           dlerror());
     return false;
   }

   lib_interface_ = reinterpret_cast<bt_vendor_interface_t*>(
       dlsym(lib_handle_, VENDOR_LIBRARY_SYMBOL_NAME));
   if (!lib_interface_) {
     ALOGE("%s unable to find symbol %s in %s (%s)", __func__,
           VENDOR_LIBRARY_SYMBOL_NAME, VENDOR_LIBRARY_NAME, dlerror());
     return false;
   }

   // Get the local BD address

   uint8_t local_bda[BluetoothAddress::kBytes];
   CHECK(BluetoothAddress::get_local_address(local_bda));
   int status = lib_interface_->init(&lib_callbacks, (unsigned char*)local_bda);
   if (status) {
     ALOGE("%s unable to initialize vendor library: %d", __func__, status);
     return false;
   }

   ALOGD("%s vendor library loaded", __func__);

   // Power cycle chip

   int power_state = BT_VND_PWR_OFF;
   lib_interface_->op(BT_VND_OP_POWER_CTRL, &power_state);
   power_state = BT_VND_PWR_ON;
   lib_interface_->op(BT_VND_OP_POWER_CTRL, &power_state);

   // Get the UART socket

   int fd_list[CH_MAX] = {0};
   int fd_count = lib_interface_->op(BT_VND_OP_USERIAL_OPEN, &fd_list);

   if (fd_count != 1) {
     ALOGE("%s fd count %d != 1; we can't handle this currently...", __func__,
           fd_count);
     return false;
   }

   uart_fd_ = fd_list[0];
   if (uart_fd_ == INVALID_FD) {
     ALOGE("%s unable to determine UART fd", __func__);
     return false;
   }

   ALOGI("%s UART fd: %d", __func__, uart_fd_);

   fd_watcher_.WatchFdForNonBlockingReads(uart_fd_,
                                          [this](int fd) { OnDataReady(fd); });

   // Initially, the power management is off.
   lpm_wake_deasserted = true;

   // Start configuring the firmware
   firmware_startup_timer_ = new FirmwareStartupTimer();
   lib_interface_->op(BT_VND_OP_FW_CFG, nullptr);

   return true;
 }

 void VendorInterface::Close() {
   fd_watcher_.StopWatchingFileDescriptor();

   if (lib_interface_ != nullptr) {
     bt_vendor_lpm_mode_t mode = BT_VND_LPM_DISABLE;
     lib_interface_->op(BT_VND_OP_LPM_SET_MODE, &mode);

     lib_interface_->op(BT_VND_OP_USERIAL_CLOSE, nullptr);
     uart_fd_ = INVALID_FD;
     int power_state = BT_VND_PWR_OFF;
     lib_interface_->op(BT_VND_OP_POWER_CTRL, &power_state);
   }

   if (lib_handle_ != nullptr) {
     dlclose(lib_handle_);
     lib_handle_ = nullptr;
   }

   if (firmware_startup_timer_ != nullptr) {
     delete firmware_startup_timer_;
     firmware_startup_timer_ = nullptr;
   }
 }

 size_t VendorInterface::Send(uint8_t type, const uint8_t* data, size_t length) {
   if (uart_fd_ == INVALID_FD) return 0;

   recent_activity_flag = true;

   if (lpm_wake_deasserted == true) {
     // Restart the timer.
     fd_watcher_.ConfigureTimeout(std::chrono::milliseconds(lpm_timeout_ms),
                                  [this]() { OnTimeout(); });
     // Assert wake.
     lpm_wake_deasserted = false;
     bt_vendor_lpm_wake_state_t wakeState = BT_VND_LPM_WAKE_ASSERT;
     lib_interface_->op(BT_VND_OP_LPM_WAKE_SET_STATE, &wakeState);
     ALOGV("%s: Sent wake before (%02x)", __func__, data[0] | (data[1] << 8));
   }

   int rv = write_safely(uart_fd_, &type, sizeof(type));
   if (rv == sizeof(type))
     rv = write_safely(uart_fd_, data, length);

   return rv;
 }

 void VendorInterface::OnFirmwareConfigured(uint8_t result) {
   ALOGD("%s result: %d", __func__, result);

   if (firmware_startup_timer_ != nullptr) {
     delete firmware_startup_timer_;
     firmware_startup_timer_ = nullptr;
   }

   if (initialize_complete_cb_ != nullptr) {
     initialize_complete_cb_(result == 0);
     initialize_complete_cb_ = nullptr;
   }

   lib_interface_->op(BT_VND_OP_GET_LPM_IDLE_TIMEOUT, &lpm_timeout_ms);
   ALOGI("%s: lpm_timeout_ms %d", __func__, lpm_timeout_ms);

   bt_vendor_lpm_mode_t mode = BT_VND_LPM_ENABLE;
   lib_interface_->op(BT_VND_OP_LPM_SET_MODE, &mode);

   ALOGD("%s Calling StartLowPowerWatchdog()", __func__);
   fd_watcher_.ConfigureTimeout(std::chrono::milliseconds(lpm_timeout_ms),
                                [this]() { OnTimeout(); });
 }

 void VendorInterface::OnTimeout() {
   ALOGV("%s", __func__);
   if (recent_activity_flag == false) {
     lpm_wake_deasserted = true;
     bt_vendor_lpm_wake_state_t wakeState = BT_VND_LPM_WAKE_DEASSERT;
     lib_interface_->op(BT_VND_OP_LPM_WAKE_SET_STATE, &wakeState);
     fd_watcher_.ConfigureTimeout(std::chrono::seconds(0), []() {
       ALOGE("Zero timeout! Should never happen.");
     });
   }
   recent_activity_flag = false;
 }

 void VendorInterface::OnDataReady(int fd) {
   switch (hci_parser_state_) {
     case HCI_IDLE: {
       uint8_t buffer[1] = {0};
       size_t bytes_read = TEMP_FAILURE_RETRY(read(fd, buffer, 1));
       CHECK(bytes_read == 1);
       hci_packet_type_ = static_cast<HciPacketType>(buffer[0]);
       // TODO(eisenbach): Check for workaround(s)
       CHECK(hci_packet_type_ >= HCI_PACKET_TYPE_ACL_DATA &&
             hci_packet_type_ <= HCI_PACKET_TYPE_EVENT)
           << "buffer[0] = " << static_cast<unsigned int>(buffer[0]);
       hci_parser_state_ = HCI_TYPE_READY;
       hci_packet_bytes_remaining_ = preamble_size_for_type[hci_packet_type_];
       hci_packet_bytes_read_ = 0;
       break;
     }

     case HCI_TYPE_READY: {
       size_t bytes_read = TEMP_FAILURE_RETRY(
           read(fd, hci_packet_preamble_ + hci_packet_bytes_read_,
                hci_packet_bytes_remaining_));
       CHECK(bytes_read > 0);
       hci_packet_bytes_remaining_ -= bytes_read;
       hci_packet_bytes_read_ += bytes_read;
       if (hci_packet_bytes_remaining_ == 0) {
         size_t packet_length =
             HciGetPacketLengthForType(hci_packet_type_, hci_packet_preamble_);
         hci_packet_.resize(preamble_size_for_type[hci_packet_type_] +
                            packet_length);
         memcpy(hci_packet_.data(), hci_packet_preamble_,
                preamble_size_for_type[hci_packet_type_]);
         hci_packet_bytes_remaining_ = packet_length;
         hci_parser_state_ = HCI_PAYLOAD;
         hci_packet_bytes_read_ = 0;
       }
       break;
     }

     case HCI_PAYLOAD: {
       size_t bytes_read = TEMP_FAILURE_RETRY(
           read(fd,
                hci_packet_.data() + preamble_size_for_type[hci_packet_type_] +
                    hci_packet_bytes_read_,
                hci_packet_bytes_remaining_));
       hci_packet_bytes_remaining_ -= bytes_read;
       hci_packet_bytes_read_ += bytes_read;
       if (hci_packet_bytes_remaining_ == 0) {
         if (internal_command.cb != nullptr &&
             hci_packet_type_ == HCI_PACKET_TYPE_EVENT &&
             internal_command_event_match(hci_packet_)) {
           HC_BT_HDR* bt_hdr =
               WrapPacketAndCopy(HCI_PACKET_TYPE_EVENT, hci_packet_);

           // The callbacks can send new commands, so don't zero after calling.
           tINT_CMD_CBACK saved_cb = internal_command.cb;
           internal_command.cb = nullptr;
           saved_cb(bt_hdr);
         } else {
           packet_read_cb_(hci_packet_type_, hci_packet_);
         }
         hci_parser_state_ = HCI_IDLE;
       }
       break;
     }
   }
 }

 }  // namespace implementation
 }  // namespace V1_0
 }  // namespace bluetooth
 }  // namespace hardware
 }  // namespace android
	//
	// Copyright 2016 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.
	//

	#include "vendor_interface.h"

	#include <assert.h>

	#define LOG_TAG "android.hardware.bluetooth@1.0-impl"
	#include <android-base/logging.h>
	#include <cutils/properties.h>
	#include <utils/Log.h>

	#include <dlfcn.h>
	#include <fcntl.h>

	#include "bluetooth_address.h"

	static const char* VENDOR_LIBRARY_NAME = "libbt-vendor.so";
	static const char* VENDOR_LIBRARY_SYMBOL_NAME =
	"BLUETOOTH_VENDOR_LIB_INTERFACE";

	static const int INVALID_FD = -1;

	namespace {

	using android::hardware::bluetooth::V1_0::implementation::VendorInterface;
	using android::hardware::hidl_vec;

	struct {
	tINT_CMD_CBACK cb;
	uint16_t opcode;
	} internal_command;

	// True when LPM is not enabled yet or wake is not asserted.
	bool lpm_wake_deasserted;
	uint32_t lpm_timeout_ms;
	bool recent_activity_flag;

	VendorInterface* g_vendor_interface = nullptr;

	const size_t preamble_size_for_type[] = {
	0, HCI_COMMAND_PREAMBLE_SIZE, HCI_ACL_PREAMBLE_SIZE, HCI_SCO_PREAMBLE_SIZE,
	HCI_EVENT_PREAMBLE_SIZE};
	const size_t packet_length_offset_for_type[] = {
	0, HCI_LENGTH_OFFSET_CMD, HCI_LENGTH_OFFSET_ACL, HCI_LENGTH_OFFSET_SCO,
	HCI_LENGTH_OFFSET_EVT};

	size_t HciGetPacketLengthForType(HciPacketType type, const uint8_t* preamble) {
	size_t offset = packet_length_offset_for_type[type];
	if (type != HCI_PACKET_TYPE_ACL_DATA) return preamble[offset];
	return (((preamble[offset + 1]) << 8) \| preamble[offset]);
	}

	HC_BT_HDR* WrapPacketAndCopy(uint16_t event, const hidl_vec<uint8_t>& data) {
	size_t packet_size = data.size() + sizeof(HC_BT_HDR);
	HC_BT_HDR* packet = reinterpret_cast<HC_BT_HDR*>(new uint8_t[packet_size]);
	packet->offset = 0;
	packet->len = data.size();
	packet->layer_specific = 0;
	packet->event = event;
	// TODO(eisenbach): Avoid copy here; if BT_HDR->data can be ensured to
	// be the only way the data is accessed, a pointer could be passed here...
	memcpy(packet->data, data.data(), data.size());
	return packet;
	}

	size_t write_safely(int fd, const uint8_t* data, size_t length) {
	size_t transmitted_length = 0;
	while (length > 0) {
	ssize_t ret =
	TEMP_FAILURE_RETRY(write(fd, data + transmitted_length, length));

	if (ret == -1) {
	if (errno == EAGAIN) continue;
	ALOGE("%s error writing to UART (%s)", __func__, strerror(errno));
	break;

	} else if (ret == 0) {
	// Nothing written :(
	ALOGE("%s zero bytes written - something went wrong...", __func__);
	break;
	}

	transmitted_length += ret;
	length -= ret;
	}

	return transmitted_length;
	}

	bool internal_command_event_match(const hidl_vec<uint8_t>& packet) {
	uint8_t event_code = packet[0];
	if (event_code != HCI_COMMAND_COMPLETE_EVENT) {
	ALOGE("%s: Unhandled event type %02X", __func__, event_code);
	return false;
	}

	size_t opcode_offset = HCI_EVENT_PREAMBLE_SIZE + 1; // Skip num packets.

	uint16_t opcode = packet[opcode_offset] \| (packet[opcode_offset + 1] << 8);

	ALOGV("%s internal_command.opcode = %04X opcode = %04x", __func__,
	internal_command.opcode, opcode);
	return opcode == internal_command.opcode;
	}

	uint8_t transmit_cb(uint16_t opcode, void* buffer, tINT_CMD_CBACK callback) {
	ALOGV("%s opcode: 0x%04x, ptr: %p, cb: %p", __func__, opcode, buffer,
	callback);
	internal_command.cb = callback;
	internal_command.opcode = opcode;
	uint8_t type = HCI_PACKET_TYPE_COMMAND;
	HC_BT_HDR* bt_hdr = reinterpret_cast<HC_BT_HDR*>(buffer);
	VendorInterface::get()->Send(type, bt_hdr->data, bt_hdr->len);
	delete[] reinterpret_cast<uint8_t*>(buffer);
	return true;
	}

	void firmware_config_cb(bt_vendor_op_result_t result) {
	ALOGV("%s result: %d", __func__, result);
	VendorInterface::get()->OnFirmwareConfigured(result);
	}

	void sco_config_cb(bt_vendor_op_result_t result) {
	ALOGD("%s result: %d", __func__, result);
	}

	void low_power_mode_cb(bt_vendor_op_result_t result) {
	ALOGD("%s result: %d", __func__, result);
	}

	void sco_audiostate_cb(bt_vendor_op_result_t result) {
	ALOGD("%s result: %d", __func__, result);
	}

	void* buffer_alloc_cb(int size) {
	void* p = new uint8_t[size];
	ALOGV("%s pts: %p, size: %d", __func__, p, size);
	return p;
	}

	void buffer_free_cb(void* buffer) {
	ALOGV("%s ptr: %p", __func__, buffer);
	delete[] reinterpret_cast<uint8_t*>(buffer);
	}

	void epilog_cb(bt_vendor_op_result_t result) {
	ALOGD("%s result: %d", __func__, result);
	}

	void a2dp_offload_cb(bt_vendor_op_result_t result, bt_vendor_opcode_t op,
	uint8_t av_handle) {
	ALOGD("%s result: %d, op: %d, handle: %d", __func__, result, op, av_handle);
	}

	const bt_vendor_callbacks_t lib_callbacks = {
	sizeof(lib_callbacks), firmware_config_cb, sco_config_cb,
	low_power_mode_cb, sco_audiostate_cb, buffer_alloc_cb,
	buffer_free_cb, transmit_cb, epilog_cb,
	a2dp_offload_cb};

	} // namespace

	namespace android {
	namespace hardware {
	namespace bluetooth {
	namespace V1_0 {
	namespace implementation {

	class FirmwareStartupTimer {
	public:
	FirmwareStartupTimer() : start_time_(std::chrono::steady_clock::now()) {}

	~FirmwareStartupTimer() {
	std::chrono::duration<double> duration =
	std::chrono::steady_clock::now() - start_time_;
	double s = duration.count();
	if (s == 0) return;
	ALOGI("Firmware configured in %.3fs", s);
	}

	private:
	std::chrono::steady_clock::time_point start_time_;
	};

	bool VendorInterface::Initialize(
	InitializeCompleteCallback initialize_complete_cb,
	PacketReadCallback packet_read_cb) {
	assert(!g_vendor_interface);
	g_vendor_interface = new VendorInterface();
	return g_vendor_interface->Open(initialize_complete_cb, packet_read_cb);
	}

	void VendorInterface::Shutdown() {
	CHECK(g_vendor_interface);
	g_vendor_interface->Close();
	delete g_vendor_interface;
	g_vendor_interface = nullptr;
	}

	VendorInterface* VendorInterface::get() { return g_vendor_interface; }

	bool VendorInterface::Open(InitializeCompleteCallback initialize_complete_cb,
	PacketReadCallback packet_read_cb) {
	initialize_complete_cb_ = initialize_complete_cb;
	packet_read_cb_ = packet_read_cb;

	// Initialize vendor interface

	lib_handle_ = dlopen(VENDOR_LIBRARY_NAME, RTLD_NOW);
	if (!lib_handle_) {
	ALOGE("%s unable to open %s (%s)", __func__, VENDOR_LIBRARY_NAME,
	dlerror());
	return false;
	}

	lib_interface_ = reinterpret_cast<bt_vendor_interface_t*>(
	dlsym(lib_handle_, VENDOR_LIBRARY_SYMBOL_NAME));
	if (!lib_interface_) {
	ALOGE("%s unable to find symbol %s in %s (%s)", __func__,
	VENDOR_LIBRARY_SYMBOL_NAME, VENDOR_LIBRARY_NAME, dlerror());
	return false;
	}

	// Get the local BD address

	uint8_t local_bda[BluetoothAddress::kBytes];
	CHECK(BluetoothAddress::get_local_address(local_bda));
	int status = lib_interface_->init(&lib_callbacks, (unsigned char*)local_bda);
	if (status) {
	ALOGE("%s unable to initialize vendor library: %d", __func__, status);
	return false;
	}

	ALOGD("%s vendor library loaded", __func__);

	// Power cycle chip

	int power_state = BT_VND_PWR_OFF;
	lib_interface_->op(BT_VND_OP_POWER_CTRL, &power_state);
	power_state = BT_VND_PWR_ON;
	lib_interface_->op(BT_VND_OP_POWER_CTRL, &power_state);

	// Get the UART socket

	int fd_list[CH_MAX] = {0};
	int fd_count = lib_interface_->op(BT_VND_OP_USERIAL_OPEN, &fd_list);

	if (fd_count != 1) {
	ALOGE("%s fd count %d != 1; we can't handle this currently...", __func__,
	fd_count);
	return false;
	}

	uart_fd_ = fd_list[0];
	if (uart_fd_ == INVALID_FD) {
	ALOGE("%s unable to determine UART fd", __func__);
	return false;
	}

	ALOGI("%s UART fd: %d", __func__, uart_fd_);

	fd_watcher_.WatchFdForNonBlockingReads(uart_fd_,
	[this](int fd) { OnDataReady(fd); });

	// Initially, the power management is off.
	lpm_wake_deasserted = true;

	// Start configuring the firmware
	firmware_startup_timer_ = new FirmwareStartupTimer();
	lib_interface_->op(BT_VND_OP_FW_CFG, nullptr);

	return true;
	}

	void VendorInterface::Close() {
	fd_watcher_.StopWatchingFileDescriptor();

	if (lib_interface_ != nullptr) {
	bt_vendor_lpm_mode_t mode = BT_VND_LPM_DISABLE;
	lib_interface_->op(BT_VND_OP_LPM_SET_MODE, &mode);

	lib_interface_->op(BT_VND_OP_USERIAL_CLOSE, nullptr);
	uart_fd_ = INVALID_FD;
	int power_state = BT_VND_PWR_OFF;
	lib_interface_->op(BT_VND_OP_POWER_CTRL, &power_state);
	}

	if (lib_handle_ != nullptr) {
	dlclose(lib_handle_);
	lib_handle_ = nullptr;
	}

	if (firmware_startup_timer_ != nullptr) {
	delete firmware_startup_timer_;
	firmware_startup_timer_ = nullptr;
	}
	}

	size_t VendorInterface::Send(uint8_t type, const uint8_t* data, size_t length) {
	if (uart_fd_ == INVALID_FD) return 0;

	recent_activity_flag = true;

	if (lpm_wake_deasserted == true) {
	// Restart the timer.
	fd_watcher_.ConfigureTimeout(std::chrono::milliseconds(lpm_timeout_ms),
	[this]() { OnTimeout(); });
	// Assert wake.
	lpm_wake_deasserted = false;
	bt_vendor_lpm_wake_state_t wakeState = BT_VND_LPM_WAKE_ASSERT;
	lib_interface_->op(BT_VND_OP_LPM_WAKE_SET_STATE, &wakeState);
	ALOGV("%s: Sent wake before (%02x)", __func__, data[0] \| (data[1] << 8));
	}

	int rv = write_safely(uart_fd_, &type, sizeof(type));
	if (rv == sizeof(type))
	rv = write_safely(uart_fd_, data, length);

	return rv;
	}

	void VendorInterface::OnFirmwareConfigured(uint8_t result) {
	ALOGD("%s result: %d", __func__, result);

	if (firmware_startup_timer_ != nullptr) {
	delete firmware_startup_timer_;
	firmware_startup_timer_ = nullptr;
	}

	if (initialize_complete_cb_ != nullptr) {
	initialize_complete_cb_(result == 0);
	initialize_complete_cb_ = nullptr;
	}

	lib_interface_->op(BT_VND_OP_GET_LPM_IDLE_TIMEOUT, &lpm_timeout_ms);
	ALOGI("%s: lpm_timeout_ms %d", __func__, lpm_timeout_ms);

	bt_vendor_lpm_mode_t mode = BT_VND_LPM_ENABLE;
	lib_interface_->op(BT_VND_OP_LPM_SET_MODE, &mode);

	ALOGD("%s Calling StartLowPowerWatchdog()", __func__);
	fd_watcher_.ConfigureTimeout(std::chrono::milliseconds(lpm_timeout_ms),
	[this]() { OnTimeout(); });
	}

	void VendorInterface::OnTimeout() {
	ALOGV("%s", __func__);
	if (recent_activity_flag == false) {
	lpm_wake_deasserted = true;
	bt_vendor_lpm_wake_state_t wakeState = BT_VND_LPM_WAKE_DEASSERT;
	lib_interface_->op(BT_VND_OP_LPM_WAKE_SET_STATE, &wakeState);
	fd_watcher_.ConfigureTimeout(std::chrono::seconds(0), []() {
	ALOGE("Zero timeout! Should never happen.");
	});
	}
	recent_activity_flag = false;
	}

	void VendorInterface::OnDataReady(int fd) {
	switch (hci_parser_state_) {
	case HCI_IDLE: {
	uint8_t buffer[1] = {0};
	size_t bytes_read = TEMP_FAILURE_RETRY(read(fd, buffer, 1));
	CHECK(bytes_read == 1);
	hci_packet_type_ = static_cast<HciPacketType>(buffer[0]);
	// TODO(eisenbach): Check for workaround(s)
	CHECK(hci_packet_type_ >= HCI_PACKET_TYPE_ACL_DATA &&
	hci_packet_type_ <= HCI_PACKET_TYPE_EVENT)
	<< "buffer[0] = " << static_cast<unsigned int>(buffer[0]);
	hci_parser_state_ = HCI_TYPE_READY;
	hci_packet_bytes_remaining_ = preamble_size_for_type[hci_packet_type_];
	hci_packet_bytes_read_ = 0;
	break;
	}

	case HCI_TYPE_READY: {
	size_t bytes_read = TEMP_FAILURE_RETRY(
	read(fd, hci_packet_preamble_ + hci_packet_bytes_read_,
	hci_packet_bytes_remaining_));
	CHECK(bytes_read > 0);
	hci_packet_bytes_remaining_ -= bytes_read;
	hci_packet_bytes_read_ += bytes_read;
	if (hci_packet_bytes_remaining_ == 0) {
	size_t packet_length =
	HciGetPacketLengthForType(hci_packet_type_, hci_packet_preamble_);
	hci_packet_.resize(preamble_size_for_type[hci_packet_type_] +
	packet_length);
	memcpy(hci_packet_.data(), hci_packet_preamble_,
	preamble_size_for_type[hci_packet_type_]);
	hci_packet_bytes_remaining_ = packet_length;
	hci_parser_state_ = HCI_PAYLOAD;
	hci_packet_bytes_read_ = 0;
	}
	break;
	}

	case HCI_PAYLOAD: {
	size_t bytes_read = TEMP_FAILURE_RETRY(
	read(fd,
	hci_packet_.data() + preamble_size_for_type[hci_packet_type_] +
	hci_packet_bytes_read_,
	hci_packet_bytes_remaining_));
	hci_packet_bytes_remaining_ -= bytes_read;
	hci_packet_bytes_read_ += bytes_read;
	if (hci_packet_bytes_remaining_ == 0) {
	if (internal_command.cb != nullptr &&
	hci_packet_type_ == HCI_PACKET_TYPE_EVENT &&
	internal_command_event_match(hci_packet_)) {
	HC_BT_HDR* bt_hdr =
	WrapPacketAndCopy(HCI_PACKET_TYPE_EVENT, hci_packet_);

	// The callbacks can send new commands, so don't zero after calling.
	tINT_CMD_CBACK saved_cb = internal_command.cb;
	internal_command.cb = nullptr;
	saved_cb(bt_hdr);
	} else {
	packet_read_cb_(hci_packet_type_, hci_packet_);
	}
	hci_parser_state_ = HCI_IDLE;
	}
	break;
	}
	}
	}

	} // namespace implementation
	} // namespace V1_0
	} // namespace bluetooth
	} // namespace hardware
	} // namespace android