esp-idf/components/bt/host/bluedroid/hci/hci_hal_h4.c

661 lines
20 KiB
C

/******************************************************************************
*
* 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.
*
******************************************************************************/
#include <string.h>
#include "common/bt_defs.h"
#include "common/bt_trace.h"
#include "stack/bt_types.h"
#include "hci/hci_hal.h"
#include "hci/hci_internals.h"
#include "hci/hci_layer.h"
#include "osi/thread.h"
#include "osi/pkt_queue.h"
#if (BLE_ADV_REPORT_FLOW_CONTROL == TRUE)
#include "osi/mutex.h"
#include "osi/alarm.h"
#endif
#include "esp_bt.h"
#include "stack/hcimsgs.h"
#if SOC_ESP_NIMBLE_CONTROLLER
#include "nimble/ble_hci_trans.h"
#endif
#if (C2H_FLOW_CONTROL_INCLUDED == TRUE)
#include "l2c_int.h"
#endif ///C2H_FLOW_CONTROL_INCLUDED == TRUE
#include "stack/hcimsgs.h"
#include "hci_log/bt_hci_log.h"
#define HCI_BLE_EVENT 0x3e
#define PACKET_TYPE_TO_INBOUND_INDEX(type) ((type) - 2)
#define PACKET_TYPE_TO_INDEX(type) ((type) - 1)
#define HCI_UPSTREAM_DATA_QUEUE_IDX (1)
#if (BLE_ADV_REPORT_FLOW_CONTROL == TRUE)
#define HCI_BLE_ADV_MIN_CREDITS_TO_RELEASE (10)
#define HCI_ADV_FLOW_MONITOR_PERIOD_MS (500)
#else
#define HCI_HAL_BLE_ADV_RPT_QUEUE_LEN_MAX (200)
#endif
extern bool BTU_check_queue_is_congest(void);
static const uint8_t preamble_sizes[] = {
HCI_COMMAND_PREAMBLE_SIZE,
HCI_ACL_PREAMBLE_SIZE,
HCI_SCO_PREAMBLE_SIZE,
HCI_EVENT_PREAMBLE_SIZE
};
static const uint16_t outbound_event_types[] = {
MSG_HC_TO_STACK_HCI_ERR,
MSG_HC_TO_STACK_HCI_ACL,
MSG_HC_TO_STACK_HCI_SCO,
MSG_HC_TO_STACK_HCI_EVT
};
typedef struct {
fixed_queue_t *rx_q;
struct pkt_queue *adv_rpt_q;
#if (BLE_ADV_REPORT_FLOW_CONTROL == TRUE)
osi_mutex_t adv_flow_lock;
osi_alarm_t *adv_flow_monitor;
int adv_credits;
int adv_credits_to_release;
pkt_linked_item_t *adv_fc_cmd_buf;
bool cmd_buf_in_use;
#endif
hci_hal_callbacks_t *callbacks;
osi_thread_t *hci_h4_thread;
struct osi_event *upstream_data_ready;
} hci_hal_env_t;
static hci_hal_env_t hci_hal_env;
static const hci_hal_t interface;
static const esp_vhci_host_callback_t vhci_host_cb;
static void host_send_pkt_available_cb(void);
static int host_recv_pkt_cb(uint8_t *data, uint16_t len);
static void hci_hal_h4_hdl_rx_packet(BT_HDR *packet);
static void hci_hal_h4_hdl_rx_adv_rpt(pkt_linked_item_t *linked_pkt);
static void hci_upstream_data_handler(void *arg);
static bool hci_upstream_data_post(uint32_t timeout);
#if (BLE_ADV_REPORT_FLOW_CONTROL == TRUE)
static void hci_adv_flow_monitor(void *context);
static void hci_adv_flow_cmd_free_cb(pkt_linked_item_t *linked_pkt);
#endif
static bool hci_hal_env_init(const hci_hal_callbacks_t *upper_callbacks, osi_thread_t *task_thread)
{
assert(upper_callbacks != NULL);
assert(task_thread != NULL);
hci_hal_env.hci_h4_thread = task_thread;
hci_hal_env.callbacks = (hci_hal_callbacks_t *)upper_callbacks;
#if (BLE_ADV_REPORT_FLOW_CONTROL == TRUE)
hci_hal_env.adv_fc_cmd_buf = osi_calloc(HCI_CMD_LINKED_BUF_SIZE(HCIC_PARAM_SIZE_BLE_UPDATE_ADV_FLOW_CONTROL));
assert(hci_hal_env.adv_fc_cmd_buf != NULL);
osi_mutex_new(&hci_hal_env.adv_flow_lock);
osi_mutex_lock(&hci_hal_env.adv_flow_lock, OSI_MUTEX_MAX_TIMEOUT);
hci_hal_env.adv_credits = BLE_ADV_REPORT_FLOW_CONTROL_NUM;
hci_hal_env.adv_credits_to_release = 0;
hci_hal_env.cmd_buf_in_use = false;
osi_mutex_unlock(&hci_hal_env.adv_flow_lock);
hci_hal_env.adv_flow_monitor = osi_alarm_new("adv_fc_mon", hci_adv_flow_monitor, NULL, HCI_ADV_FLOW_MONITOR_PERIOD_MS);
assert (hci_hal_env.adv_flow_monitor != NULL);
#endif
hci_hal_env.rx_q = fixed_queue_new(QUEUE_SIZE_MAX);
assert(hci_hal_env.rx_q != NULL);
hci_hal_env.adv_rpt_q = pkt_queue_create();
assert(hci_hal_env.adv_rpt_q != NULL);
struct osi_event *event = osi_event_create(hci_upstream_data_handler, NULL);
assert(event != NULL);
hci_hal_env.upstream_data_ready = event;
osi_event_bind(hci_hal_env.upstream_data_ready, hci_hal_env.hci_h4_thread, HCI_UPSTREAM_DATA_QUEUE_IDX);
return true;
}
static void hci_hal_env_deinit(void)
{
fixed_queue_t *rx_q = hci_hal_env.rx_q;
struct pkt_queue *adv_rpt_q = hci_hal_env.adv_rpt_q;
struct osi_event *upstream_data_ready = hci_hal_env.upstream_data_ready;
hci_hal_env.rx_q = NULL;
hci_hal_env.adv_rpt_q = NULL;
hci_hal_env.upstream_data_ready = NULL;
fixed_queue_free(rx_q, osi_free_func);
pkt_queue_destroy(adv_rpt_q, NULL);
osi_event_delete(upstream_data_ready);
#if (BLE_ADV_REPORT_FLOW_CONTROL == TRUE)
hci_hal_env.cmd_buf_in_use = true;
osi_alarm_cancel(hci_hal_env.adv_flow_monitor);
osi_alarm_free(hci_hal_env.adv_flow_monitor);
hci_hal_env.adv_flow_monitor = NULL;
osi_mutex_free(&hci_hal_env.adv_flow_lock);
osi_free(hci_hal_env.adv_fc_cmd_buf);
hci_hal_env.adv_fc_cmd_buf = NULL;
#endif
hci_hal_env.hci_h4_thread = NULL;
memset(&hci_hal_env, 0, sizeof(hci_hal_env_t));
}
static bool hal_open(const hci_hal_callbacks_t *upper_callbacks, void *task_thread)
{
hci_hal_env_init(upper_callbacks, (osi_thread_t *)task_thread);
//register vhci host cb
if (esp_vhci_host_register_callback(&vhci_host_cb) != ESP_OK) {
return false;
}
return true;
}
static void hal_close(void)
{
hci_hal_env_deinit();
}
/**
* Function: transmit_data -TX data to low-layer
* It is ported from Bluedroid source code, so it is not
* needed to use write() to send data.
* TODO: Just use firmware API to send data.
*/
static uint16_t transmit_data(serial_data_type_t type,
uint8_t *data, uint16_t length)
{
uint8_t previous_byte;
assert(data != NULL);
assert(length > 0);
if (type < DATA_TYPE_COMMAND || type > DATA_TYPE_SCO) {
HCI_TRACE_ERROR("%s invalid data type: %d", __func__, type);
return 0;
}
// Write the signal byte right before the data
--data;
previous_byte = *data;
*(data) = type;
++length;
BTTRC_DUMP_BUFFER("Transmit Pkt", data, length);
#if (BT_HCI_LOG_INCLUDED == TRUE)
bt_hci_log_record_hci_data(data[0], data, length);
#endif
// TX Data to target
esp_vhci_host_send_packet(data, length);
// Be nice and restore the old value of that byte
*(data) = previous_byte;
return length - 1;
}
// Internal functions
static void hci_upstream_data_handler(void *arg)
{
fixed_queue_t *rx_q = hci_hal_env.rx_q;
struct pkt_queue *adv_rpt_q = hci_hal_env.adv_rpt_q;
size_t pkts_to_process;
do {
pkts_to_process = fixed_queue_length(rx_q);
for (size_t i = 0; i < pkts_to_process; i++) {
BT_HDR *packet = fixed_queue_dequeue(rx_q, 0);
if (packet != NULL) {
hci_hal_h4_hdl_rx_packet(packet);
}
}
} while (0);
do {
pkts_to_process = pkt_queue_length(adv_rpt_q);
for (size_t i = 0; i < pkts_to_process; i++) {
pkt_linked_item_t *linked_pkt = pkt_queue_dequeue(adv_rpt_q);
if (linked_pkt != NULL) {
hci_hal_h4_hdl_rx_adv_rpt(linked_pkt);
}
}
} while (0);
if (!fixed_queue_is_empty(rx_q) || pkt_queue_length(adv_rpt_q) > 0) {
hci_upstream_data_post(OSI_THREAD_MAX_TIMEOUT);
}
}
static bool hci_upstream_data_post(uint32_t timeout)
{
return osi_thread_post_event(hci_hal_env.upstream_data_ready, timeout);
}
#if (C2H_FLOW_CONTROL_INCLUDED == TRUE)
static void hci_packet_complete(BT_HDR *packet){
uint8_t type;
uint16_t handle;
uint16_t num_packets = 1;
uint8_t *stream = packet->data + packet->offset;
STREAM_TO_UINT8(type, stream);
if (type == DATA_TYPE_ACL/* || type == DATA_TYPE_SCO*/) {
STREAM_TO_UINT16(handle, stream);
handle = handle & HCI_DATA_HANDLE_MASK;
btsnd_hcic_host_num_xmitted_pkts(1, &handle, &num_packets);
}
}
#endif ///C2H_FLOW_CONTROL_INCLUDED == TRUE
bool host_recv_adv_packet(uint8_t *packet)
{
assert(packet);
if(packet[0] == DATA_TYPE_EVENT && packet[1] == HCI_BLE_EVENT) {
if(packet[3] == HCI_BLE_ADV_PKT_RPT_EVT || packet[3] == HCI_BLE_DIRECT_ADV_EVT
#if (BLE_ADV_REPORT_FLOW_CONTROL == TRUE)
|| packet[3] == HCI_BLE_ADV_DISCARD_REPORT_EVT
#endif
) {
return true;
}
}
return false;
}
#if (BLE_ADV_REPORT_FLOW_CONTROL == TRUE)
static void hci_adv_flow_monitor(void *context)
{
hci_adv_credits_force_release(0);
}
static void hci_adv_credits_consumed(uint16_t num)
{
osi_mutex_lock(&hci_hal_env.adv_flow_lock, OSI_MUTEX_MAX_TIMEOUT);
assert(hci_hal_env.adv_credits >= num);
hci_hal_env.adv_credits -= num;
osi_mutex_unlock(&hci_hal_env.adv_flow_lock);
}
int hci_adv_credits_prep_to_release(uint16_t num)
{
if (num == 0) {
return hci_hal_env.adv_credits_to_release;
}
osi_mutex_lock(&hci_hal_env.adv_flow_lock, OSI_MUTEX_MAX_TIMEOUT);
int credits_to_release = hci_hal_env.adv_credits_to_release + num;
assert(hci_hal_env.adv_credits_to_release <= BLE_ADV_REPORT_FLOW_CONTROL_NUM);
hci_hal_env.adv_credits_to_release = credits_to_release;
osi_mutex_unlock(&hci_hal_env.adv_flow_lock);
if (credits_to_release == num && num != 0) {
osi_alarm_cancel(hci_hal_env.adv_flow_monitor);
osi_alarm_set(hci_hal_env.adv_flow_monitor, HCI_ADV_FLOW_MONITOR_PERIOD_MS);
}
return credits_to_release;
}
static int hci_adv_credits_release(void)
{
osi_mutex_lock(&hci_hal_env.adv_flow_lock, OSI_MUTEX_MAX_TIMEOUT);
int credits_released = hci_hal_env.adv_credits_to_release;
hci_hal_env.adv_credits += credits_released;
hci_hal_env.adv_credits_to_release -= credits_released;
assert(hci_hal_env.adv_credits <= BLE_ADV_REPORT_FLOW_CONTROL_NUM);
assert(hci_hal_env.adv_credits_to_release >= 0);
osi_mutex_unlock(&hci_hal_env.adv_flow_lock);
if (hci_hal_env.adv_credits_to_release == 0) {
osi_alarm_cancel(hci_hal_env.adv_flow_monitor);
}
return credits_released;
}
static int hci_adv_credits_release_rollback(uint16_t num)
{
osi_mutex_lock(&hci_hal_env.adv_flow_lock, OSI_MUTEX_MAX_TIMEOUT);
hci_hal_env.adv_credits -= num;
hci_hal_env.adv_credits_to_release += num;
assert(hci_hal_env.adv_credits >=0);
assert(hci_hal_env.adv_credits_to_release <= BLE_ADV_REPORT_FLOW_CONTROL_NUM);
osi_mutex_unlock(&hci_hal_env.adv_flow_lock);
return num;
}
static void hci_adv_flow_cmd_free_cb(pkt_linked_item_t *linked_pkt)
{
osi_mutex_lock(&hci_hal_env.adv_flow_lock, OSI_MUTEX_MAX_TIMEOUT);
hci_hal_env.cmd_buf_in_use = false;
osi_mutex_unlock(&hci_hal_env.adv_flow_lock);
hci_adv_credits_try_release(0);
}
bool hci_adv_flow_try_send_command(uint16_t credits_released)
{
bool sent = false;
bool use_static_buffer = false;
/* first try using static buffer, then dynamic buffer */
if (!hci_hal_env.cmd_buf_in_use) {
osi_mutex_lock(&hci_hal_env.adv_flow_lock, OSI_MUTEX_MAX_TIMEOUT);
if (!hci_hal_env.cmd_buf_in_use) {
hci_hal_env.cmd_buf_in_use = true;
use_static_buffer = true;
}
osi_mutex_unlock(&hci_hal_env.adv_flow_lock);
}
if (use_static_buffer) {
hci_cmd_metadata_t *metadata = (hci_cmd_metadata_t *)(hci_hal_env.adv_fc_cmd_buf->data);
BT_HDR *static_buffer = &metadata->command;
metadata->command_free_cb = hci_adv_flow_cmd_free_cb;
sent = btsnd_hcic_ble_update_adv_report_flow_control(credits_released, static_buffer);
} else {
sent = btsnd_hcic_ble_update_adv_report_flow_control(credits_released, NULL);
}
return sent;
}
int hci_adv_credits_try_release(uint16_t num)
{
int credits_released = 0;
if (hci_adv_credits_prep_to_release(num) >= HCI_BLE_ADV_MIN_CREDITS_TO_RELEASE) {
credits_released = hci_adv_credits_release();
if (credits_released > 0) {
if (!hci_adv_flow_try_send_command(credits_released)) {
hci_adv_credits_release_rollback(credits_released);
}
} else {
assert (credits_released == 0);
}
}
return credits_released;
}
int hci_adv_credits_force_release(uint16_t num)
{
hci_adv_credits_prep_to_release(num);
int credits_released = hci_adv_credits_release();
if (credits_released > 0) {
if (!hci_adv_flow_try_send_command(credits_released)) {
hci_adv_credits_release_rollback(credits_released);
}
}
return credits_released;
}
#endif
static void hci_hal_h4_hdl_rx_packet(BT_HDR *packet)
{
uint8_t type, hdr_size;
uint16_t length;
uint8_t *stream = NULL;
if (!packet) {
return;
}
stream = packet->data + packet->offset;
#if (C2H_FLOW_CONTROL_INCLUDED == TRUE)
hci_packet_complete(packet);
#endif ///C2H_FLOW_CONTROL_INCLUDED == TRUE
STREAM_TO_UINT8(type, stream);
packet->offset++;
packet->len--;
if (type == HCI_BLE_EVENT) {
#if (!CONFIG_BT_STACK_NO_LOG)
uint8_t len = 0;
STREAM_TO_UINT8(len, stream);
#endif
HCI_TRACE_ERROR("Workaround stream corrupted during LE SCAN: pkt_len=%d ble_event_len=%d\n",
packet->len, len);
osi_free(packet);
return;
}
if (type < DATA_TYPE_ACL || type > DATA_TYPE_EVENT) {
HCI_TRACE_ERROR("%s Unknown HCI message type. Dropping this byte 0x%x,"
" min %x, max %x\n", __func__, type,
DATA_TYPE_ACL, DATA_TYPE_EVENT);
osi_free(packet);
return;
}
hdr_size = preamble_sizes[type - 1];
if (packet->len < hdr_size) {
HCI_TRACE_ERROR("Wrong packet length type=%d pkt_len=%d hdr_len=%d",
type, packet->len, hdr_size);
osi_free(packet);
return;
}
if (type == DATA_TYPE_ACL) {
stream += hdr_size - 2;
STREAM_TO_UINT16(length, stream);
} else {
stream += hdr_size - 1;
STREAM_TO_UINT8(length, stream);
}
if ((length + hdr_size) != packet->len) {
HCI_TRACE_ERROR("Wrong packet length type=%d hdr_len=%d pd_len=%d "
"pkt_len=%d", type, hdr_size, length, packet->len);
osi_free(packet);
return;
}
packet->event = outbound_event_types[PACKET_TYPE_TO_INDEX(type)];
hci_hal_env.callbacks->packet_ready(packet);
}
static void hci_hal_h4_hdl_rx_adv_rpt(pkt_linked_item_t *linked_pkt)
{
uint8_t type;
uint8_t hdr_size;
uint16_t length;
uint8_t *stream = NULL;
if (!linked_pkt) {
return;
}
BT_HDR* packet = (BT_HDR *)linked_pkt->data;
stream = packet->data + packet->offset;
assert(host_recv_adv_packet(stream) == true);
STREAM_TO_UINT8(type, stream);
packet->offset++;
packet->len--;
hdr_size = preamble_sizes[type - 1];
if (packet->len < hdr_size) {
HCI_TRACE_ERROR("Wrong packet length type=%d pkt_len=%d hdr_len=%d",
type, packet->len, hdr_size);
goto _discard_packet;
}
stream += hdr_size - 1;
STREAM_TO_UINT8(length, stream);
if ((length + hdr_size) != packet->len) {
HCI_TRACE_ERROR("Wrong packet length type=%d hdr_len=%d pd_len=%d "
"pkt_len=%d", type, hdr_size, length, packet->len);
goto _discard_packet;
}
#if SCAN_QUEUE_CONGEST_CHECK
if(BTU_check_queue_is_congest()) {
HCI_TRACE_DEBUG("BtuQueue is congested");
goto _discard_packet;
}
#endif
packet->event = outbound_event_types[PACKET_TYPE_TO_INDEX(type)];
hci_hal_env.callbacks->adv_rpt_ready(linked_pkt);
return;
_discard_packet:
osi_free(linked_pkt);
#if (BLE_ADV_REPORT_FLOW_CONTROL == TRUE)
hci_adv_credits_prep_to_release(1);
#endif
}
static void host_send_pkt_available_cb(void)
{
//Controller rx cache buffer is ready for receiving new host packet
//Just Call Host main thread task to process pending packets.
hci_downstream_data_post(OSI_THREAD_MAX_TIMEOUT);
}
static int host_recv_pkt_cb(uint8_t *data, uint16_t len)
{
//Target has packet to host, malloc new buffer for packet
BT_HDR *pkt = NULL;
pkt_linked_item_t *linked_pkt = NULL;
size_t pkt_size;
if (hci_hal_env.rx_q == NULL) {
return 0;
}
bool is_adv_rpt = host_recv_adv_packet(data);
if (!is_adv_rpt) {
#if (BT_HCI_LOG_INCLUDED == TRUE)
uint8_t data_type = ((data[0] == 2) ? HCI_LOG_DATA_TYPE_C2H_ACL : data[0]);
bt_hci_log_record_hci_data(data_type, data, len);
#endif // (BT_HCI_LOG_INCLUDED == TRUE)
pkt_size = BT_HDR_SIZE + len;
pkt = (BT_HDR *) osi_calloc(pkt_size);
if (!pkt) {
HCI_TRACE_ERROR("%s couldn't acquire memory for inbound data buffer.\n", __func__);
assert(0);
}
pkt->offset = 0;
pkt->len = len;
pkt->layer_specific = 0;
memcpy(pkt->data, data, len);
fixed_queue_enqueue(hci_hal_env.rx_q, pkt, FIXED_QUEUE_MAX_TIMEOUT);
} else {
#if (BT_HCI_LOG_INCLUDED == TRUE)
// data type is adv report
bt_hci_log_record_hci_adv(HCI_LOG_DATA_TYPE_ADV, data, len);
#endif // (BT_HCI_LOG_INCLUDED == TRUE)
#if !BLE_ADV_REPORT_FLOW_CONTROL
// drop the packets if pkt_queue length goes beyond upper limit
if (pkt_queue_length(hci_hal_env.adv_rpt_q) > HCI_HAL_BLE_ADV_RPT_QUEUE_LEN_MAX) {
return 0;
}
#endif
pkt_size = BT_PKT_LINKED_HDR_SIZE + BT_HDR_SIZE + len;
linked_pkt = (pkt_linked_item_t *) osi_calloc(pkt_size);
if (!linked_pkt) {
#if (BLE_ADV_REPORT_FLOW_CONTROL == TRUE)
hci_adv_credits_consumed(1);
hci_adv_credits_prep_to_release(1);
#endif
return 0;
}
pkt = (BT_HDR *)linked_pkt->data;
pkt->offset = 0;
pkt->len = len;
pkt->layer_specific = 0;
memcpy(pkt->data, data, len);
pkt_queue_enqueue(hci_hal_env.adv_rpt_q, linked_pkt);
#if (BLE_ADV_REPORT_FLOW_CONTROL == TRUE)
hci_adv_credits_consumed(1);
#endif
}
hci_upstream_data_post(OSI_THREAD_MAX_TIMEOUT);
BTTRC_DUMP_BUFFER("Recv Pkt", pkt->data, len);
return 0;
}
#if SOC_ESP_NIMBLE_CONTROLLER
int
ble_hs_hci_rx_evt(uint8_t *hci_ev, void *arg)
{
if(esp_bluedroid_get_status() == ESP_BLUEDROID_STATUS_UNINITIALIZED) {
ble_hci_trans_buf_free(hci_ev);
return 0;
}
uint16_t len = hci_ev[1] + 3;
uint8_t *data = (uint8_t *)malloc(len);
assert(data != NULL);
data[0] = 0x04;
memcpy(&data[1], hci_ev, len - 1);
ble_hci_trans_buf_free(hci_ev);
host_recv_pkt_cb(data, len);
free(data);
return 0;
}
int
ble_hs_rx_data(struct os_mbuf *om, void *arg)
{
uint16_t len = OS_MBUF_PKTHDR(om)->omp_len + 1;
uint8_t *data = (uint8_t *)malloc(len);
assert(data != NULL);
data[0] = 0x02;
os_mbuf_copydata(om, 0, len - 1, &data[1]);
host_recv_pkt_cb(data, len);
free(data);
os_mbuf_free_chain(om);
return 0;
}
#endif
static const esp_vhci_host_callback_t vhci_host_cb = {
.notify_host_send_available = host_send_pkt_available_cb,
.notify_host_recv = host_recv_pkt_cb,
};
static const hci_hal_t interface = {
hal_open,
hal_close,
transmit_data,
};
const hci_hal_t *hci_hal_h4_get_interface(void)
{
return &interface;
}