path: root/hci/src/packet_fragmenter.cc

/******************************************************************************
 *
 *  Copyright (C) 2014 Google, Inc.
 *
 *  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.
 *
 ******************************************************************************/

#define LOG_TAG "bt_hci_packet_fragmenter"

#include "packet_fragmenter.h"

#include <base/logging.h>
#include <string.h>
#include <unordered_map>

#include "bt_target.h"
#include "buffer_allocator.h"
#include "device/include/controller.h"
#include "hci_internals.h"
#include "osi/include/log.h"
#include "osi/include/osi.h"

#define APPLY_CONTINUATION_FLAG(handle) (((handle)&0xCFFF) | 0x1000)
#define APPLY_START_FLAG(handle) (((handle)&0xCFFF) | 0x2000)
#define SUB_EVENT(event) ((event)&MSG_SUB_EVT_MASK)
#define GET_BOUNDARY_FLAG(handle) (((handle) >> 12) & 0x0003)
#define GET_BROADCAST_FLAG(handle) (((handle) >> 14) & 0x0003)

#define HANDLE_MASK 0x0FFF
#define START_PACKET_BOUNDARY 2
#define CONTINUATION_PACKET_BOUNDARY 1
#define POINT_TO_POINT 0
#define L2CAP_HEADER_SIZE 4

// Our interface and callbacks

static const allocator_t* buffer_allocator;
static const controller_t* controller;
static const packet_fragmenter_callbacks_t* callbacks;

static std::unordered_map<uint16_t /* handle */, BT_HDR*> partial_packets;

static void init(const packet_fragmenter_callbacks_t* result_callbacks) {
  callbacks = result_callbacks;
}

static void cleanup() { partial_packets.clear(); }

static void fragment_and_dispatch(BT_HDR* packet) {
  CHECK(packet != NULL);

  uint16_t event = packet->event & MSG_EVT_MASK;
  uint8_t* stream = packet->data + packet->offset;

  // We only fragment ACL packets
  if (event != MSG_STACK_TO_HC_HCI_ACL) {
    callbacks->fragmented(packet, true);
    return;
  }

  uint16_t max_data_size =
      SUB_EVENT(packet->event) == LOCAL_BR_EDR_CONTROLLER_ID
          ? controller->get_acl_data_size_classic()
          : controller->get_acl_data_size_ble();

  uint16_t max_packet_size = max_data_size + HCI_ACL_PREAMBLE_SIZE;
  uint16_t remaining_length = packet->len;

  uint16_t continuation_handle;
  STREAM_TO_UINT16(continuation_handle, stream);
  continuation_handle = APPLY_CONTINUATION_FLAG(continuation_handle);

  while (remaining_length > max_packet_size) {
    // Make sure we use the right ACL packet size
    stream = packet->data + packet->offset;
    STREAM_SKIP_UINT16(stream);
    UINT16_TO_STREAM(stream, max_data_size);

    packet->len = max_packet_size;
    callbacks->fragmented(packet, false);

    packet->offset += max_data_size;
    remaining_length -= max_data_size;
    packet->len = remaining_length;

    // Write the ACL header for the next fragment
    stream = packet->data + packet->offset;
    UINT16_TO_STREAM(stream, continuation_handle);
    UINT16_TO_STREAM(stream, remaining_length - HCI_ACL_PREAMBLE_SIZE);

    // Apparently L2CAP can set layer_specific to a max number of segments to
    // transmit
    if (packet->layer_specific) {
      packet->layer_specific--;

      if (packet->layer_specific == 0) {
        packet->event = MSG_HC_TO_STACK_L2C_SEG_XMIT;
        callbacks->transmit_finished(packet, false);
        return;
      }
    }
  }

  callbacks->fragmented(packet, true);
}

static bool check_uint16_overflow(uint16_t a, uint16_t b) {
  return (UINT16_MAX - a) < b;
}

static void reassemble_and_dispatch(BT_HDR* packet) {
  if ((packet->event & MSG_EVT_MASK) == MSG_HC_TO_STACK_HCI_ACL) {
    uint8_t* stream = packet->data;
    uint16_t handle;
    uint16_t acl_length;

    STREAM_TO_UINT16(handle, stream);
    STREAM_TO_UINT16(acl_length, stream);

    CHECK(acl_length == packet->len - HCI_ACL_PREAMBLE_SIZE);

    uint8_t boundary_flag = GET_BOUNDARY_FLAG(handle);
    uint8_t broadcast_flag = GET_BROADCAST_FLAG(handle);
    handle = handle & HANDLE_MASK;

    if (broadcast_flag != POINT_TO_POINT) {
      LOG_WARN(LOG_TAG, "dropping broadcast packet");
      android_errorWriteLog(0x534e4554, "169327567");
      buffer_allocator->free(packet);
      return;
    }

    if (boundary_flag == START_PACKET_BOUNDARY) {
      if (acl_length < 2) {
        LOG_WARN(LOG_TAG, "%s invalid acl_length %d", __func__, acl_length);
        buffer_allocator->free(packet);
        return;
      }
      auto map_iter = partial_packets.find(handle);
      if (map_iter != partial_packets.end()) {
        LOG_WARN(LOG_TAG,
                 "%s found unfinished packet for handle with start packet. "
                 "Dropping old.",
                 __func__);

        BT_HDR* hdl = map_iter->second;
        partial_packets.erase(map_iter);
        buffer_allocator->free(hdl);
      }

      if (acl_length < L2CAP_HEADER_SIZE) {
        LOG_WARN(LOG_TAG, "%s L2CAP packet too small (%d < %d). Dropping it.",
                 __func__, packet->len, L2CAP_HEADER_SIZE);
        buffer_allocator->free(packet);
        return;
      }

      uint16_t l2cap_length;
      STREAM_TO_UINT16(l2cap_length, stream);

      uint16_t full_length =
          l2cap_length + L2CAP_HEADER_SIZE + HCI_ACL_PREAMBLE_SIZE;

      // Check for buffer overflow and that the full packet size + BT_HDR size
      // is less than the max buffer size
      if (check_uint16_overflow(l2cap_length,
                                (L2CAP_HEADER_SIZE + HCI_ACL_PREAMBLE_SIZE)) ||
          ((full_length + sizeof(BT_HDR)) > BT_DEFAULT_BUFFER_SIZE)) {
        LOG_ERROR(LOG_TAG, "%s Dropping L2CAP packet with invalid length (%d).",
                  __func__, l2cap_length);
        buffer_allocator->free(packet);
        return;
      }

      if (full_length <= packet->len) {
        if (full_length < packet->len)
          LOG_WARN(LOG_TAG,
                   "%s found l2cap full length %d less than the hci length %d.",
                   __func__, l2cap_length, packet->len);

        callbacks->reassembled(packet);
        return;
      }

      BT_HDR* partial_packet =
          (BT_HDR*)buffer_allocator->alloc(full_length + sizeof(BT_HDR));
      partial_packet->event = packet->event;
      partial_packet->len = full_length;
      partial_packet->offset = packet->len;

      memcpy(partial_packet->data, packet->data, packet->len);

      // Update the ACL data size to indicate the full expected length
      stream = partial_packet->data;
      STREAM_SKIP_UINT16(stream);  // skip the handle
      UINT16_TO_STREAM(stream, full_length - HCI_ACL_PREAMBLE_SIZE);

      partial_packets[handle] = partial_packet;

      // Free the old packet buffer, since we don't need it anymore
      buffer_allocator->free(packet);
    } else {
      auto map_iter = partial_packets.find(handle);
      if (map_iter == partial_packets.end()) {
        LOG_WARN(LOG_TAG,
                 "%s got continuation for unknown packet. Dropping it.",
                 __func__);
        buffer_allocator->free(packet);
        return;
      }
      BT_HDR* partial_packet = map_iter->second;

      packet->offset = HCI_ACL_PREAMBLE_SIZE;
      uint16_t projected_offset =
          partial_packet->offset + (packet->len - HCI_ACL_PREAMBLE_SIZE);
      if ((packet->len - packet->offset) >
          (partial_packet->len - partial_packet->offset)) {
        LOG_WARN(LOG_TAG,
                 "%s got packet which would exceed expected length of %d. "
                 "Truncating.",
                 __func__, partial_packet->len);
        packet->len = (partial_packet->len - partial_packet->offset) + packet->offset;
        projected_offset = partial_packet->len;
      }

      memcpy(partial_packet->data + partial_packet->offset,
             packet->data + packet->offset, packet->len - packet->offset);

      // Free the old packet buffer, since we don't need it anymore
      buffer_allocator->free(packet);
      partial_packet->offset = projected_offset;

      if (partial_packet->offset == partial_packet->len) {
        partial_packets.erase(handle);
        partial_packet->offset = 0;
        callbacks->reassembled(partial_packet);
      }
    }
  } else {
    callbacks->reassembled(packet);
  }
}

static const packet_fragmenter_t interface = {init, cleanup,

                                              fragment_and_dispatch,
                                              reassemble_and_dispatch};

const packet_fragmenter_t* packet_fragmenter_get_interface() {
  controller = controller_get_interface();
  buffer_allocator = buffer_allocator_get_interface();
  return &interface;
}

const packet_fragmenter_t* packet_fragmenter_get_test_interface(
    const controller_t* controller_interface,
    const allocator_t* buffer_allocator_interface) {
  controller = controller_interface;
  buffer_allocator = buffer_allocator_interface;
  return &interface;
}