zephyr/subsys/bluetooth/controller/hci/hci_driver.c

452 lines
9.6 KiB
C

/*
* Copyright (c) 2016 Nordic Semiconductor ASA
* Copyright (c) 2016 Vinayak Kariappa Chettimada
*
* SPDX-License-Identifier: Apache-2.0
*/
#include <errno.h>
#include <stddef.h>
#include <string.h>
#include <zephyr.h>
#include <soc.h>
#include <init.h>
#include <device.h>
#include <clock_control.h>
#include <atomic.h>
#include <misc/util.h>
#include <misc/stack.h>
#include <misc/byteorder.h>
#include <bluetooth/bluetooth.h>
#include <bluetooth/hci.h>
#include <drivers/bluetooth/hci_driver.h>
#ifdef CONFIG_CLOCK_CONTROL_NRF5
#include <drivers/clock_control/nrf5_clock_control.h>
#endif
#define BT_DBG_ENABLED IS_ENABLED(CONFIG_BT_DEBUG_HCI_DRIVER)
#include "common/log.h"
#include "util/util.h"
#include "hal/ccm.h"
#include "hal/radio.h"
#include "ll_sw/pdu.h"
#include "ll_sw/ctrl.h"
#include "ll.h"
#include "hci_internal.h"
#include "hal/debug.h"
#define NODE_RX(_node) CONTAINER_OF(_node, struct radio_pdu_node_rx, \
hdr.onion.node)
static K_SEM_DEFINE(sem_prio_recv, 0, UINT_MAX);
static K_FIFO_DEFINE(recv_fifo);
struct k_thread prio_recv_thread_data;
static BT_STACK_NOINIT(prio_recv_thread_stack,
CONFIG_BT_CTLR_RX_PRIO_STACK_SIZE);
struct k_thread recv_thread_data;
static BT_STACK_NOINIT(recv_thread_stack, CONFIG_BT_RX_STACK_SIZE);
#if defined(CONFIG_INIT_STACKS)
static u32_t prio_ts;
static u32_t rx_ts;
#endif
#if defined(CONFIG_BT_HCI_ACL_FLOW_CONTROL)
static struct k_poll_signal hbuf_signal =
K_POLL_SIGNAL_INITIALIZER(hbuf_signal);
static sys_slist_t hbuf_pend;
static s32_t hbuf_count;
#endif
static void prio_recv_thread(void *p1, void *p2, void *p3)
{
while (1) {
struct radio_pdu_node_rx *node_rx;
u8_t num_cmplt;
u16_t handle;
while ((num_cmplt = radio_rx_get(&node_rx, &handle))) {
#if defined(CONFIG_BT_CONN)
struct net_buf *buf;
buf = bt_buf_get_rx(BT_BUF_EVT, K_FOREVER);
hci_num_cmplt_encode(buf, handle, num_cmplt);
BT_DBG("Num Complete: 0x%04x:%u", handle, num_cmplt);
bt_recv_prio(buf);
k_yield();
#endif
}
if (node_rx) {
radio_rx_dequeue();
BT_DBG("RX node enqueue");
k_fifo_put(&recv_fifo, node_rx);
continue;
}
BT_DBG("sem take...");
k_sem_take(&sem_prio_recv, K_FOREVER);
BT_DBG("sem taken");
#if defined(CONFIG_INIT_STACKS)
if (k_uptime_get_32() - prio_ts > K_SECONDS(5)) {
STACK_ANALYZE("prio recv thread stack",
prio_recv_thread_stack);
prio_ts = k_uptime_get_32();
}
#endif
}
}
static inline struct net_buf *encode_node(struct radio_pdu_node_rx *node_rx,
s8_t class)
{
struct net_buf *buf = NULL;
/* Check if we need to generate an HCI event or ACL data */
switch (class) {
case HCI_CLASS_EVT_DISCARDABLE:
case HCI_CLASS_EVT_REQUIRED:
case HCI_CLASS_EVT_CONNECTION:
if (class == HCI_CLASS_EVT_DISCARDABLE) {
buf = bt_buf_get_rx(BT_BUF_EVT, K_NO_WAIT);
} else {
buf = bt_buf_get_rx(BT_BUF_EVT, K_FOREVER);
}
if (buf) {
hci_evt_encode(node_rx, buf);
}
break;
#if defined(CONFIG_BT_CONN)
case HCI_CLASS_ACL_DATA:
/* generate ACL data */
buf = bt_buf_get_rx(BT_BUF_ACL_IN, K_FOREVER);
hci_acl_encode(node_rx, buf);
break;
#endif
default:
LL_ASSERT(0);
break;
}
radio_rx_fc_set(node_rx->hdr.handle, 0);
node_rx->hdr.onion.next = 0;
radio_rx_mem_release(&node_rx);
return buf;
}
static inline struct net_buf *process_node(struct radio_pdu_node_rx *node_rx)
{
s8_t class = hci_get_class(node_rx);
struct net_buf *buf = NULL;
#if defined(CONFIG_BT_HCI_ACL_FLOW_CONTROL)
if (hbuf_count != -1) {
bool pend = !sys_slist_is_empty(&hbuf_pend);
/* controller to host flow control enabled */
switch (class) {
case HCI_CLASS_EVT_DISCARDABLE:
case HCI_CLASS_EVT_REQUIRED:
break;
case HCI_CLASS_EVT_CONNECTION:
/* for conn-related events, only pend is relevant */
hbuf_count = 1;
/* fallthrough */
case HCI_CLASS_ACL_DATA:
if (pend || !hbuf_count) {
sys_slist_append(&hbuf_pend,
&node_rx->hdr.onion.node);
BT_DBG("FC: Queuing item: %d", class);
return NULL;
}
break;
default:
LL_ASSERT(0);
break;
}
}
#endif
/* process regular node from radio */
buf = encode_node(node_rx, class);
return buf;
}
#if defined(CONFIG_BT_HCI_ACL_FLOW_CONTROL)
static inline struct net_buf *process_hbuf(void)
{
/* shadow total count in case of preemption */
s32_t hbuf_total = hci_hbuf_total;
struct net_buf *buf = NULL;
int reset;
reset = atomic_test_and_clear_bit(&hci_state_mask, HCI_STATE_BIT_RESET);
if (reset) {
/* flush queue, no need to free, the LL has already done it */
sys_slist_init(&hbuf_pend);
}
if (hbuf_total > 0) {
struct radio_pdu_node_rx *node_rx = NULL;
s8_t class, next_class = -1;
sys_snode_t *node = NULL;
/* available host buffers */
hbuf_count = hbuf_total - (hci_hbuf_sent - hci_hbuf_acked);
/* host acked ACL packets, try to dequeue from hbuf */
node = sys_slist_peek_head(&hbuf_pend);
if (node) {
node_rx = NODE_RX(node);
class = hci_get_class(node_rx);
switch (class) {
case HCI_CLASS_EVT_CONNECTION:
BT_DBG("FC: dequeueing event");
node = sys_slist_get(&hbuf_pend);
break;
case HCI_CLASS_ACL_DATA:
if (hbuf_count) {
BT_DBG("FC: dequeueing ACL data");
node = sys_slist_get(&hbuf_pend);
hbuf_count--;
} else {
/* no buffers, HCI will signal */
node = NULL;
}
break;
case HCI_CLASS_EVT_DISCARDABLE:
case HCI_CLASS_EVT_REQUIRED:
default:
LL_ASSERT(0);
break;
}
if (node) {
struct radio_pdu_node_rx *next;
bool empty = true;
node_rx = NODE_RX(node);
node = sys_slist_peek_head(&hbuf_pend);
if (node) {
next = NODE_RX(node);
next_class = hci_get_class(next);
}
empty = sys_slist_is_empty(&hbuf_pend);
buf = encode_node(node_rx, class);
if (!empty && (class == HCI_CLASS_EVT_CONNECTION ||
(class == HCI_CLASS_ACL_DATA &&
hbuf_count))) {
/* more to process, schedule an
* iteration
*/
BT_DBG("FC: signalling");
k_poll_signal(&hbuf_signal, 0x0);
}
}
}
} else {
hbuf_count = -1;
}
return buf;
}
#endif
static void recv_thread(void *p1, void *p2, void *p3)
{
#if defined(CONFIG_BT_HCI_ACL_FLOW_CONTROL)
/* @todo: check if the events structure really needs to be static */
static struct k_poll_event events[2] = {
K_POLL_EVENT_STATIC_INITIALIZER(K_POLL_TYPE_SIGNAL,
K_POLL_MODE_NOTIFY_ONLY,
&hbuf_signal, 0),
K_POLL_EVENT_STATIC_INITIALIZER(K_POLL_TYPE_FIFO_DATA_AVAILABLE,
K_POLL_MODE_NOTIFY_ONLY,
&recv_fifo, 0),
};
#endif
while (1) {
struct radio_pdu_node_rx *node_rx = NULL;
struct net_buf *buf = NULL;
BT_DBG("blocking");
#if defined(CONFIG_BT_HCI_ACL_FLOW_CONTROL)
int err;
err = k_poll(events, 2, K_FOREVER);
LL_ASSERT(err == 0);
if (events[0].state == K_POLL_STATE_SIGNALED) {
events[0].signal->signaled = 0;
} else if (events[1].state ==
K_POLL_STATE_FIFO_DATA_AVAILABLE) {
node_rx = k_fifo_get(events[1].fifo, 0);
}
events[0].state = K_POLL_STATE_NOT_READY;
events[1].state = K_POLL_STATE_NOT_READY;
/* process host buffers first if any */
buf = process_hbuf();
#else
node_rx = k_fifo_get(&recv_fifo, K_FOREVER);
#endif
BT_DBG("unblocked");
if (node_rx && !buf) {
/* process regular node from radio */
buf = process_node(node_rx);
}
if (buf) {
if (buf->len) {
BT_DBG("Packet in: type:%u len:%u",
bt_buf_get_type(buf), buf->len);
bt_recv(buf);
} else {
net_buf_unref(buf);
}
}
k_yield();
#if defined(CONFIG_INIT_STACKS)
if (k_uptime_get_32() - rx_ts > K_SECONDS(5)) {
STACK_ANALYZE("recv thread stack", recv_thread_stack);
rx_ts = k_uptime_get_32();
}
#endif
}
}
static int cmd_handle(struct net_buf *buf)
{
struct net_buf *evt;
evt = hci_cmd_handle(buf);
if (evt) {
BT_DBG("Replying with event of %u bytes", evt->len);
bt_recv_prio(evt);
}
return 0;
}
#if defined(CONFIG_BT_CONN)
static int acl_handle(struct net_buf *buf)
{
struct net_buf *evt;
int err;
err = hci_acl_handle(buf, &evt);
if (evt) {
BT_DBG("Replying with event of %u bytes", evt->len);
bt_recv_prio(evt);
}
return err;
}
#endif /* CONFIG_BT_CONN */
static int hci_driver_send(struct net_buf *buf)
{
u8_t type;
int err;
BT_DBG("enter");
if (!buf->len) {
BT_ERR("Empty HCI packet");
return -EINVAL;
}
type = bt_buf_get_type(buf);
switch (type) {
#if defined(CONFIG_BT_CONN)
case BT_BUF_ACL_OUT:
err = acl_handle(buf);
break;
#endif /* CONFIG_BT_CONN */
case BT_BUF_CMD:
err = cmd_handle(buf);
break;
default:
BT_ERR("Unknown HCI type %u", type);
return -EINVAL;
}
if (!err) {
net_buf_unref(buf);
}
BT_DBG("exit: %d", err);
return err;
}
static int hci_driver_open(void)
{
u32_t err;
DEBUG_INIT();
err = ll_init(&sem_prio_recv);
if (err) {
BT_ERR("LL initialization failed: %u", err);
return err;
}
#if defined(CONFIG_BT_HCI_ACL_FLOW_CONTROL)
hci_init(&hbuf_signal);
#else
hci_init(NULL);
#endif
k_thread_create(&prio_recv_thread_data, prio_recv_thread_stack,
K_THREAD_STACK_SIZEOF(prio_recv_thread_stack),
prio_recv_thread, NULL, NULL, NULL,
K_PRIO_COOP(CONFIG_BT_CTLR_RX_PRIO), 0, K_NO_WAIT);
k_thread_create(&recv_thread_data, recv_thread_stack,
K_THREAD_STACK_SIZEOF(recv_thread_stack),
recv_thread, NULL, NULL, NULL,
K_PRIO_COOP(CONFIG_BT_RX_PRIO), 0, K_NO_WAIT);
BT_DBG("Success.");
return 0;
}
static const struct bt_hci_driver drv = {
.name = "Controller",
.bus = BT_HCI_DRIVER_BUS_VIRTUAL,
.open = hci_driver_open,
.send = hci_driver_send,
};
static int _hci_driver_init(struct device *unused)
{
ARG_UNUSED(unused);
bt_hci_driver_register(&drv);
return 0;
}
SYS_INIT(_hci_driver_init, POST_KERNEL, CONFIG_KERNEL_INIT_PRIORITY_DEVICE);