blob: 9c26f87bc7e2535ffe0a647d45885fe51eadffda [file] [log] [blame]
/* Copyright (c) 2012-2017, The Linux Foundation. All rights reserved.
*
* This program is free software; you can redistribute it and/or modify
* it under the terms of the GNU General Public License version 2 and
* only version 2 as published by the Free Software Foundation.
*
* This program is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*/
#include <linux/slab.h>
#include <linux/init.h>
#include <linux/uaccess.h>
#include <linux/diagchar.h>
#include <linux/sched.h>
#include <linux/err.h>
#include <linux/delay.h>
#include <linux/workqueue.h>
#include <linux/pm_runtime.h>
#include <linux/platform_device.h>
#include <linux/pm_wakeup.h>
#include <linux/spinlock.h>
#include <linux/ratelimit.h>
#include <linux/reboot.h>
#include <asm/current.h>
#include <soc/qcom/restart.h>
#ifdef CONFIG_DIAG_OVER_USB
#include <linux/usb/usbdiag.h>
#endif
#include "diagchar_hdlc.h"
#include "diagmem.h"
#include "diagchar.h"
#include "diagfwd.h"
#include "diagfwd_cntl.h"
#include "diag_dci.h"
#include "diag_masks.h"
#include "diagfwd_bridge.h"
#include "diagfwd_peripheral.h"
#include "diag_ipc_logging.h"
static struct timer_list dci_drain_timer;
static int dci_timer_in_progress;
static struct work_struct dci_data_drain_work;
struct diag_dci_partial_pkt_t partial_pkt;
unsigned int dci_max_reg = 100;
unsigned int dci_max_clients = 10;
struct mutex dci_log_mask_mutex;
struct mutex dci_event_mask_mutex;
/*
* DCI_HANDSHAKE_RETRY_TIME: Time to wait (in microseconds) before checking the
* connection status again.
*
* DCI_HANDSHAKE_WAIT_TIME: Timeout (in milliseconds) to check for dci
* connection status
*/
#define DCI_HANDSHAKE_RETRY_TIME 500000
#define DCI_HANDSHAKE_WAIT_TIME 200
spinlock_t ws_lock;
unsigned long ws_lock_flags;
struct dci_ops_tbl_t dci_ops_tbl[NUM_DCI_PROC] = {
{
.ctx = 0,
.send_log_mask = diag_send_dci_log_mask,
.send_event_mask = diag_send_dci_event_mask,
.peripheral_status = 0,
.mempool = 0,
},
#ifdef CONFIG_DIAGFWD_BRIDGE_CODE
{
.ctx = DIAGFWD_MDM_DCI,
.send_log_mask = diag_send_dci_log_mask_remote,
.send_event_mask = diag_send_dci_event_mask_remote,
.peripheral_status = 0,
.mempool = POOL_TYPE_MDM_DCI_WRITE,
}
#endif
};
struct dci_channel_status_t dci_channel_status[NUM_DCI_PROC] = {
{
.id = 0,
.open = 0,
.retry_count = 0
},
#ifdef CONFIG_DIAGFWD_BRIDGE_CODE
{
.id = DIAGFWD_MDM_DCI,
.open = 0,
.retry_count = 0
}
#endif
};
/* Number of milliseconds anticipated to process the DCI data */
#define DCI_WAKEUP_TIMEOUT 1
#define DCI_CAN_ADD_BUF_TO_LIST(buf) \
(buf && buf->data && !buf->in_busy && buf->data_len > 0) \
#ifdef CONFIG_DEBUG_FS
struct diag_dci_data_info *dci_traffic;
struct mutex dci_stat_mutex;
void diag_dci_record_traffic(int read_bytes, uint8_t ch_type,
uint8_t peripheral, uint8_t proc)
{
static int curr_dci_data;
static unsigned long iteration;
struct diag_dci_data_info *temp_data = dci_traffic;
if (!temp_data)
return;
mutex_lock(&dci_stat_mutex);
if (curr_dci_data == DIAG_DCI_DEBUG_CNT)
curr_dci_data = 0;
temp_data += curr_dci_data;
temp_data->iteration = iteration + 1;
temp_data->data_size = read_bytes;
temp_data->peripheral = peripheral;
temp_data->ch_type = ch_type;
temp_data->proc = proc;
diag_get_timestamp(temp_data->time_stamp);
curr_dci_data++;
iteration++;
mutex_unlock(&dci_stat_mutex);
}
#else
void diag_dci_record_traffic(int read_bytes, uint8_t ch_type,
uint8_t peripheral, uint8_t proc) { }
#endif
static void create_dci_log_mask_tbl(unsigned char *mask, uint8_t dirty)
{
unsigned char *temp = mask;
uint8_t i;
if (!mask)
return;
/* create hard coded table for log mask with 16 categories */
for (i = 0; i < DCI_MAX_LOG_CODES; i++) {
*temp = i;
temp++;
*temp = dirty ? 1 : 0;
temp++;
memset(temp, 0, DCI_MAX_ITEMS_PER_LOG_CODE);
temp += DCI_MAX_ITEMS_PER_LOG_CODE;
}
}
static void create_dci_event_mask_tbl(unsigned char *tbl_buf)
{
if (tbl_buf)
memset(tbl_buf, 0, DCI_EVENT_MASK_SIZE);
}
void dci_drain_data(unsigned long data)
{
queue_work(driver->diag_dci_wq, &dci_data_drain_work);
}
static void dci_check_drain_timer(void)
{
if (!dci_timer_in_progress) {
dci_timer_in_progress = 1;
mod_timer(&dci_drain_timer, jiffies + msecs_to_jiffies(200));
}
}
#ifdef CONFIG_DIAGFWD_BRIDGE_CODE
static void dci_handshake_work_fn(struct work_struct *work)
{
int err = 0;
int max_retries = 5;
struct dci_channel_status_t *status = container_of(work,
struct dci_channel_status_t,
handshake_work);
if (status->open) {
pr_debug("diag: In %s, remote dci channel is open, index: %d\n",
__func__, status->id);
return;
}
if (status->retry_count == max_retries) {
status->retry_count = 0;
pr_info("diag: dci channel connection handshake timed out, id: %d\n",
status->id);
err = diagfwd_bridge_close(TOKEN_TO_BRIDGE(status->id));
if (err) {
pr_err("diag: In %s, unable to close dci channel id: %d, err: %d\n",
__func__, status->id, err);
}
return;
}
status->retry_count++;
/*
* Sleep for sometime to check for the connection status again. The
* value should be optimum to include a roundabout time for a small
* packet to the remote processor.
*/
usleep_range(DCI_HANDSHAKE_RETRY_TIME, DCI_HANDSHAKE_RETRY_TIME + 100);
mod_timer(&status->wait_time,
jiffies + msecs_to_jiffies(DCI_HANDSHAKE_WAIT_TIME));
}
static void dci_chk_handshake(unsigned long data)
{
int index = (int)data;
if (index < 0 || index >= NUM_DCI_PROC)
return;
queue_work(driver->diag_dci_wq,
&dci_channel_status[index].handshake_work);
}
#endif
static int diag_dci_init_buffer(struct diag_dci_buffer_t *buffer, int type)
{
if (!buffer || buffer->data)
return -EINVAL;
switch (type) {
case DCI_BUF_PRIMARY:
buffer->capacity = IN_BUF_SIZE;
buffer->data = kzalloc(buffer->capacity, GFP_KERNEL);
if (!buffer->data)
return -ENOMEM;
break;
case DCI_BUF_SECONDARY:
buffer->data = NULL;
buffer->capacity = IN_BUF_SIZE;
break;
case DCI_BUF_CMD:
buffer->capacity = DIAG_MAX_REQ_SIZE + DCI_BUF_SIZE;
buffer->data = kzalloc(buffer->capacity, GFP_KERNEL);
if (!buffer->data)
return -ENOMEM;
break;
default:
pr_err("diag: In %s, unknown type %d", __func__, type);
return -EINVAL;
}
buffer->data_len = 0;
buffer->in_busy = 0;
buffer->buf_type = type;
mutex_init(&buffer->data_mutex);
return 0;
}
static inline int diag_dci_check_buffer(struct diag_dci_buffer_t *buf, int len)
{
if (!buf)
return -EINVAL;
/* Return 1 if the buffer is not busy and can hold new data */
if ((buf->data_len + len < buf->capacity) && !buf->in_busy)
return 1;
return 0;
}
static void dci_add_buffer_to_list(struct diag_dci_client_tbl *client,
struct diag_dci_buffer_t *buf)
{
if (!buf || !client || !buf->data)
return;
if (buf->in_list || buf->data_len == 0)
return;
mutex_lock(&client->write_buf_mutex);
list_add_tail(&buf->buf_track, &client->list_write_buf);
/*
* In the case of DCI, there can be multiple packets in one read. To
* calculate the wakeup source reference count, we must account for each
* packet in a single read.
*/
diag_ws_on_read(DIAG_WS_DCI, buf->data_len);
mutex_lock(&buf->data_mutex);
buf->in_busy = 1;
buf->in_list = 1;
mutex_unlock(&buf->data_mutex);
mutex_unlock(&client->write_buf_mutex);
}
static int diag_dci_get_buffer(struct diag_dci_client_tbl *client,
int data_source, int len)
{
struct diag_dci_buffer_t *buf_primary = NULL;
struct diag_dci_buffer_t *buf_temp = NULL;
struct diag_dci_buffer_t *curr = NULL;
if (!client)
return -EINVAL;
if (len < 0 || len > IN_BUF_SIZE)
return -EINVAL;
curr = client->buffers[data_source].buf_curr;
buf_primary = client->buffers[data_source].buf_primary;
if (curr && diag_dci_check_buffer(curr, len) == 1)
return 0;
dci_add_buffer_to_list(client, curr);
client->buffers[data_source].buf_curr = NULL;
if (diag_dci_check_buffer(buf_primary, len) == 1) {
client->buffers[data_source].buf_curr = buf_primary;
return 0;
}
buf_temp = kzalloc(sizeof(struct diag_dci_buffer_t), GFP_KERNEL);
if (!buf_temp)
return -EIO;
if (!diag_dci_init_buffer(buf_temp, DCI_BUF_SECONDARY)) {
buf_temp->data = diagmem_alloc(driver, IN_BUF_SIZE,
POOL_TYPE_DCI);
if (!buf_temp->data) {
kfree(buf_temp);
buf_temp = NULL;
return -ENOMEM;
}
client->buffers[data_source].buf_curr = buf_temp;
return 0;
}
kfree(buf_temp);
buf_temp = NULL;
return -EIO;
}
void diag_dci_wakeup_clients(void)
{
struct list_head *start, *temp;
struct diag_dci_client_tbl *entry = NULL;
mutex_lock(&driver->dci_mutex);
list_for_each_safe(start, temp, &driver->dci_client_list) {
entry = list_entry(start, struct diag_dci_client_tbl, track);
/*
* Don't wake up the client when there is no pending buffer to
* write or when it is writing to user space
*/
if (!list_empty(&entry->list_write_buf) && !entry->in_service) {
mutex_lock(&entry->write_buf_mutex);
entry->in_service = 1;
mutex_unlock(&entry->write_buf_mutex);
diag_update_sleeping_process(entry->client->tgid,
DCI_DATA_TYPE);
}
}
mutex_unlock(&driver->dci_mutex);
}
void dci_data_drain_work_fn(struct work_struct *work)
{
int i;
struct list_head *start, *temp;
struct diag_dci_client_tbl *entry = NULL;
struct diag_dci_buf_peripheral_t *proc_buf = NULL;
struct diag_dci_buffer_t *buf_temp = NULL;
mutex_lock(&driver->dci_mutex);
list_for_each_safe(start, temp, &driver->dci_client_list) {
entry = list_entry(start, struct diag_dci_client_tbl, track);
for (i = 0; i < entry->num_buffers; i++) {
proc_buf = &entry->buffers[i];
mutex_lock(&proc_buf->buf_mutex);
buf_temp = proc_buf->buf_primary;
if (DCI_CAN_ADD_BUF_TO_LIST(buf_temp))
dci_add_buffer_to_list(entry, buf_temp);
buf_temp = proc_buf->buf_cmd;
if (DCI_CAN_ADD_BUF_TO_LIST(buf_temp))
dci_add_buffer_to_list(entry, buf_temp);
buf_temp = proc_buf->buf_curr;
if (DCI_CAN_ADD_BUF_TO_LIST(buf_temp)) {
dci_add_buffer_to_list(entry, buf_temp);
proc_buf->buf_curr = NULL;
}
mutex_unlock(&proc_buf->buf_mutex);
}
if (!list_empty(&entry->list_write_buf) && !entry->in_service) {
mutex_lock(&entry->write_buf_mutex);
entry->in_service = 1;
mutex_unlock(&entry->write_buf_mutex);
diag_update_sleeping_process(entry->client->tgid,
DCI_DATA_TYPE);
}
}
mutex_unlock(&driver->dci_mutex);
dci_timer_in_progress = 0;
}
static int diag_process_single_dci_pkt(unsigned char *buf, int len,
int data_source, int token)
{
uint8_t cmd_code = 0;
if (!buf || len < 0) {
pr_err("diag: Invalid input in %s, buf: %pK, len: %d\n",
__func__, buf, len);
return -EIO;
}
cmd_code = *(uint8_t *)buf;
switch (cmd_code) {
case LOG_CMD_CODE:
extract_dci_log(buf, len, data_source, token, NULL);
break;
case EVENT_CMD_CODE:
extract_dci_events(buf, len, data_source, token, NULL);
break;
case EXT_HDR_CMD_CODE:
extract_dci_ext_pkt(buf, len, data_source, token);
break;
case DCI_PKT_RSP_CODE:
case DCI_DELAYED_RSP_CODE:
extract_dci_pkt_rsp(buf, len, data_source, token);
break;
case DCI_CONTROL_PKT_CODE:
extract_dci_ctrl_pkt(buf, len, token);
break;
default:
pr_err("diag: Unable to process single DCI packet, cmd_code: %d, data_source: %d",
cmd_code, data_source);
return -EINVAL;
}
return 0;
}
/* Process the data read from apps userspace client */
void diag_process_apps_dci_read_data(int data_type, void *buf, int recd_bytes)
{
int err = 0;
if (!buf) {
pr_err_ratelimited("diag: In %s, Null buf pointer\n", __func__);
return;
}
if (data_type != DATA_TYPE_DCI_LOG && data_type != DATA_TYPE_DCI_EVENT
&& data_type != DCI_PKT_TYPE) {
pr_err("diag: In %s, unsupported data_type: 0x%x\n",
__func__, (unsigned int)data_type);
return;
}
err = diag_process_single_dci_pkt(buf, recd_bytes, APPS_DATA,
DCI_LOCAL_PROC);
if (err)
return;
/* wake up all sleeping DCI clients which have some data */
diag_dci_wakeup_clients();
dci_check_drain_timer();
}
void diag_process_remote_dci_read_data(int index, void *buf, int recd_bytes)
{
int read_bytes = 0, err = 0;
uint16_t dci_pkt_len;
struct diag_dci_header_t *header = NULL;
int header_len = sizeof(struct diag_dci_header_t);
int token = BRIDGE_TO_TOKEN(index);
if (!buf)
return;
diag_dci_record_traffic(recd_bytes, 0, 0, token);
if (!partial_pkt.processing)
goto start;
if (partial_pkt.remaining > recd_bytes) {
if ((partial_pkt.read_len + recd_bytes) >
(MAX_DCI_PACKET_SZ)) {
pr_err("diag: Invalid length %d, %d received in %s\n",
partial_pkt.read_len, recd_bytes, __func__);
goto end;
}
memcpy(partial_pkt.data + partial_pkt.read_len, buf,
recd_bytes);
read_bytes += recd_bytes;
buf += read_bytes;
partial_pkt.read_len += recd_bytes;
partial_pkt.remaining -= recd_bytes;
} else {
if ((partial_pkt.read_len + partial_pkt.remaining) >
(MAX_DCI_PACKET_SZ)) {
pr_err("diag: Invalid length during partial read %d, %d received in %s\n",
partial_pkt.read_len,
partial_pkt.remaining, __func__);
goto end;
}
memcpy(partial_pkt.data + partial_pkt.read_len, buf,
partial_pkt.remaining);
read_bytes += partial_pkt.remaining;
buf += read_bytes;
partial_pkt.read_len += partial_pkt.remaining;
partial_pkt.remaining = 0;
}
if (partial_pkt.remaining == 0) {
/*
* Retrieve from the DCI control packet after the header = start
* (1 byte) + version (1 byte) + length (2 bytes)
*/
diag_process_single_dci_pkt(partial_pkt.data + 4,
partial_pkt.read_len - header_len,
DCI_REMOTE_DATA, token);
partial_pkt.read_len = 0;
partial_pkt.total_len = 0;
partial_pkt.processing = 0;
goto start;
}
goto end;
start:
while (read_bytes < recd_bytes) {
header = (struct diag_dci_header_t *)buf;
dci_pkt_len = header->length;
if (header->cmd_code != DCI_CONTROL_PKT_CODE &&
driver->num_dci_client == 0) {
read_bytes += header_len + dci_pkt_len;
buf += header_len + dci_pkt_len;
continue;
}
if (dci_pkt_len + header_len > MAX_DCI_PACKET_SZ) {
pr_err("diag: Invalid length in the dci packet field %d\n",
dci_pkt_len);
break;
}
if ((dci_pkt_len + header_len) > (recd_bytes - read_bytes)) {
partial_pkt.read_len = recd_bytes - read_bytes;
partial_pkt.total_len = dci_pkt_len + header_len;
partial_pkt.remaining = partial_pkt.total_len -
partial_pkt.read_len;
partial_pkt.processing = 1;
memcpy(partial_pkt.data, buf, partial_pkt.read_len);
break;
}
/*
* Retrieve from the DCI control packet after the header = start
* (1 byte) + version (1 byte) + length (2 bytes)
*/
err = diag_process_single_dci_pkt(buf + 4, dci_pkt_len,
DCI_REMOTE_DATA, DCI_MDM_PROC);
if (err)
break;
read_bytes += header_len + dci_pkt_len;
buf += header_len + dci_pkt_len; /* advance to next DCI pkt */
}
end:
if (err)
return;
/* wake up all sleeping DCI clients which have some data */
diag_dci_wakeup_clients();
dci_check_drain_timer();
}
/* Process the data read from the peripheral dci channels */
void diag_dci_process_peripheral_data(struct diagfwd_info *p_info, void *buf,
int recd_bytes)
{
int read_bytes = 0, err = 0;
uint16_t dci_pkt_len;
struct diag_dci_pkt_header_t *header = NULL;
uint8_t recv_pkt_cmd_code;
if (!buf || !p_info)
return;
/*
* Release wakeup source when there are no more clients to
* process DCI data
*/
if (driver->num_dci_client == 0) {
diag_ws_reset(DIAG_WS_DCI);
return;
}
diag_dci_record_traffic(recd_bytes, p_info->type, p_info->peripheral,
DCI_LOCAL_PROC);
while (read_bytes < recd_bytes) {
header = (struct diag_dci_pkt_header_t *)buf;
recv_pkt_cmd_code = header->pkt_code;
dci_pkt_len = header->len;
/*
* Check if the length of the current packet is lesser than the
* remaining bytes in the received buffer. This includes space
* for the Start byte (1), Version byte (1), length bytes (2)
* and End byte (1)
*/
if ((dci_pkt_len + 5) > (recd_bytes - read_bytes)) {
pr_err("diag: Invalid length in %s, len: %d, dci_pkt_len: %d",
__func__, recd_bytes, dci_pkt_len);
diag_ws_release();
return;
}
/*
* Retrieve from the DCI control packet after the header = start
* (1 byte) + version (1 byte) + length (2 bytes)
*/
err = diag_process_single_dci_pkt(buf + 4, dci_pkt_len,
(int)p_info->peripheral,
DCI_LOCAL_PROC);
if (err) {
diag_ws_release();
break;
}
read_bytes += 5 + dci_pkt_len;
buf += 5 + dci_pkt_len; /* advance to next DCI pkt */
}
if (err)
return;
/* wake up all sleeping DCI clients which have some data */
diag_dci_wakeup_clients();
dci_check_drain_timer();
}
int diag_dci_query_log_mask(struct diag_dci_client_tbl *entry,
uint16_t log_code)
{
uint16_t item_num;
uint8_t equip_id, *log_mask_ptr, byte_mask;
int byte_index, offset;
if (!entry) {
pr_err("diag: In %s, invalid client entry\n", __func__);
return 0;
}
equip_id = LOG_GET_EQUIP_ID(log_code);
item_num = LOG_GET_ITEM_NUM(log_code);
byte_index = item_num/8 + 2;
byte_mask = 0x01 << (item_num % 8);
offset = equip_id * 514;
if (offset + byte_index > DCI_LOG_MASK_SIZE) {
pr_err("diag: In %s, invalid offset: %d, log_code: %d, byte_index: %d\n",
__func__, offset, log_code, byte_index);
return 0;
}
log_mask_ptr = entry->dci_log_mask;
log_mask_ptr = log_mask_ptr + offset + byte_index;
return ((*log_mask_ptr & byte_mask) == byte_mask) ? 1 : 0;
}
int diag_dci_query_event_mask(struct diag_dci_client_tbl *entry,
uint16_t event_id)
{
uint8_t *event_mask_ptr, byte_mask;
int byte_index, bit_index;
if (!entry) {
pr_err("diag: In %s, invalid client entry\n", __func__);
return 0;
}
byte_index = event_id/8;
bit_index = event_id % 8;
byte_mask = 0x1 << bit_index;
if (byte_index > DCI_EVENT_MASK_SIZE) {
pr_err("diag: In %s, invalid, event_id: %d, byte_index: %d\n",
__func__, event_id, byte_index);
return 0;
}
event_mask_ptr = entry->dci_event_mask;
event_mask_ptr = event_mask_ptr + byte_index;
return ((*event_mask_ptr & byte_mask) == byte_mask) ? 1 : 0;
}
static int diag_dci_filter_commands(struct diag_pkt_header_t *header)
{
if (!header)
return -ENOMEM;
switch (header->cmd_code) {
case 0x7d: /* Msg Mask Configuration */
case 0x73: /* Log Mask Configuration */
case 0x81: /* Event Mask Configuration */
case 0x82: /* Event Mask Change */
case 0x60: /* Event Mask Toggle */
return 1;
}
if (header->cmd_code == 0x4b && header->subsys_id == 0x12) {
switch (header->subsys_cmd_code) {
case 0x60: /* Extended Event Mask Config */
case 0x61: /* Extended Msg Mask Config */
case 0x62: /* Extended Log Mask Config */
case 0x20C: /* Set current Preset ID */
case 0x20D: /* Get current Preset ID */
case 0x218: /* HDLC Disabled Command */
return 1;
}
}
return 0;
}
static struct dci_pkt_req_entry_t *diag_register_dci_transaction(int uid,
int client_id)
{
struct dci_pkt_req_entry_t *entry = NULL;
entry = kzalloc(sizeof(struct dci_pkt_req_entry_t), GFP_KERNEL);
if (!entry)
return NULL;
driver->dci_tag++;
entry->client_id = client_id;
entry->uid = uid;
entry->tag = driver->dci_tag;
pr_debug("diag: Registering DCI cmd req, client_id: %d, uid: %d, tag:%d\n",
entry->client_id, entry->uid, entry->tag);
list_add_tail(&entry->track, &driver->dci_req_list);
return entry;
}
static struct dci_pkt_req_entry_t *diag_dci_get_request_entry(int tag)
{
struct list_head *start, *temp;
struct dci_pkt_req_entry_t *entry = NULL;
list_for_each_safe(start, temp, &driver->dci_req_list) {
entry = list_entry(start, struct dci_pkt_req_entry_t, track);
if (entry->tag == tag)
return entry;
}
return NULL;
}
static int diag_dci_remove_req_entry(unsigned char *buf, int len,
struct dci_pkt_req_entry_t *entry)
{
uint16_t rsp_count = 0, delayed_rsp_id = 0;
if (!buf || len <= 0 || !entry) {
pr_err("diag: In %s, invalid input buf: %pK, len: %d, entry: %pK\n",
__func__, buf, len, entry);
return -EIO;
}
/* It is an immediate response, delete it from the table */
if (*buf != 0x80) {
list_del(&entry->track);
kfree(entry);
return 1;
}
/* It is a delayed response. Check if the length is valid */
if (len < MIN_DELAYED_RSP_LEN) {
pr_err("diag: Invalid delayed rsp packet length %d\n", len);
return -EINVAL;
}
/*
* If the delayed response id field (uint16_t at byte 8) is 0 then
* there is only one response and we can remove the request entry.
*/
delayed_rsp_id = *(uint16_t *)(buf + 8);
if (delayed_rsp_id == 0) {
list_del(&entry->track);
kfree(entry);
return 1;
}
/*
* Check the response count field (uint16 at byte 10). The request
* entry can be deleted it it is the last response in the sequence.
* It is the last response in the sequence if the response count
* is 1 or if the signed bit gets dropped.
*/
rsp_count = *(uint16_t *)(buf + 10);
if (rsp_count > 0 && rsp_count < 0x1000) {
list_del(&entry->track);
kfree(entry);
return 1;
}
return 0;
}
static void dci_process_ctrl_status(unsigned char *buf, int len, int token)
{
struct diag_ctrl_dci_status *header = NULL;
unsigned char *temp = buf;
uint32_t read_len = 0;
uint8_t i;
int peripheral_mask, status;
if (!buf || (len < sizeof(struct diag_ctrl_dci_status))) {
pr_err("diag: In %s, invalid buf %pK or length: %d\n",
__func__, buf, len);
return;
}
if (!VALID_DCI_TOKEN(token)) {
pr_err("diag: In %s, invalid DCI token %d\n", __func__, token);
return;
}
header = (struct diag_ctrl_dci_status *)temp;
temp += sizeof(struct diag_ctrl_dci_status);
read_len += sizeof(struct diag_ctrl_dci_status);
for (i = 0; i < header->count; i++) {
if (read_len > len) {
pr_err("diag: In %s, Invalid length len: %d\n",
__func__, len);
return;
}
switch (*(uint8_t *)temp) {
case PERIPHERAL_MODEM:
peripheral_mask = DIAG_CON_MPSS;
break;
case PERIPHERAL_LPASS:
peripheral_mask = DIAG_CON_LPASS;
break;
case PERIPHERAL_WCNSS:
peripheral_mask = DIAG_CON_WCNSS;
break;
case PERIPHERAL_SENSORS:
peripheral_mask = DIAG_CON_SENSORS;
break;
default:
pr_err("diag: In %s, unknown peripheral, peripheral: %d\n",
__func__, *(uint8_t *)temp);
return;
}
temp += sizeof(uint8_t);
read_len += sizeof(uint8_t);
status = (*(uint8_t *)temp) ? DIAG_STATUS_OPEN :
DIAG_STATUS_CLOSED;
temp += sizeof(uint8_t);
read_len += sizeof(uint8_t);
diag_dci_notify_client(peripheral_mask, status, token);
}
}
static void dci_process_ctrl_handshake_pkt(unsigned char *buf, int len,
int token)
{
struct diag_ctrl_dci_handshake_pkt *header = NULL;
unsigned char *temp = buf;
int err = 0;
if (!buf || (len < sizeof(struct diag_ctrl_dci_handshake_pkt)))
return;
if (!VALID_DCI_TOKEN(token))
return;
header = (struct diag_ctrl_dci_handshake_pkt *)temp;
if (header->magic == DCI_MAGIC) {
dci_channel_status[token].open = 1;
err = dci_ops_tbl[token].send_log_mask(token);
if (err) {
pr_err("diag: In %s, unable to send log mask to token: %d, err: %d\n",
__func__, token, err);
}
err = dci_ops_tbl[token].send_event_mask(token);
if (err) {
pr_err("diag: In %s, unable to send event mask to token: %d, err: %d\n",
__func__, token, err);
}
}
}
void extract_dci_ctrl_pkt(unsigned char *buf, int len, int token)
{
unsigned char *temp = buf;
uint32_t ctrl_pkt_id;
diag_ws_on_read(DIAG_WS_DCI, len);
if (!buf) {
pr_err("diag: Invalid buffer in %s\n", __func__);
goto err;
}
if (len < (sizeof(uint8_t) + sizeof(uint32_t))) {
pr_err("diag: In %s, invalid length %d\n", __func__, len);
goto err;
}
/* Skip the Control packet command code */
temp += sizeof(uint8_t);
len -= sizeof(uint8_t);
ctrl_pkt_id = *(uint32_t *)temp;
switch (ctrl_pkt_id) {
case DIAG_CTRL_MSG_DCI_CONNECTION_STATUS:
dci_process_ctrl_status(temp, len, token);
break;
case DIAG_CTRL_MSG_DCI_HANDSHAKE_PKT:
dci_process_ctrl_handshake_pkt(temp, len, token);
break;
default:
pr_debug("diag: In %s, unknown control pkt %d\n",
__func__, ctrl_pkt_id);
break;
}
err:
/*
* DCI control packets are not consumed by the clients. Mimic client
* consumption by setting and clearing the wakeup source copy_count
* explicitly.
*/
diag_ws_on_copy_fail(DIAG_WS_DCI);
}
void extract_dci_pkt_rsp(unsigned char *buf, int len, int data_source,
int token)
{
int tag;
struct diag_dci_client_tbl *entry = NULL;
void *temp_buf = NULL;
uint8_t dci_cmd_code, cmd_code_len, delete_flag = 0;
uint32_t rsp_len = 0;
struct diag_dci_buffer_t *rsp_buf = NULL;
struct dci_pkt_req_entry_t *req_entry = NULL;
unsigned char *temp = buf;
int save_req_uid = 0;
struct diag_dci_pkt_rsp_header_t pkt_rsp_header;
if (!buf) {
pr_err("diag: Invalid pointer in %s\n", __func__);
return;
}
dci_cmd_code = *(uint8_t *)(temp);
if (dci_cmd_code == DCI_PKT_RSP_CODE) {
cmd_code_len = sizeof(uint8_t);
} else if (dci_cmd_code == DCI_DELAYED_RSP_CODE) {
cmd_code_len = sizeof(uint32_t);
} else {
pr_err("diag: In %s, invalid command code %d\n", __func__,
dci_cmd_code);
return;
}
temp += cmd_code_len;
tag = *(int *)temp;
temp += sizeof(int);
/*
* The size of the response is (total length) - (length of the command
* code, the tag (int)
*/
rsp_len = len - (cmd_code_len + sizeof(int));
if ((rsp_len == 0) || (rsp_len > (len - 5))) {
pr_err("diag: Invalid length in %s, len: %d, rsp_len: %d",
__func__, len, rsp_len);
return;
}
mutex_lock(&driver->dci_mutex);
req_entry = diag_dci_get_request_entry(tag);
if (!req_entry) {
pr_err_ratelimited("diag: No matching client for DCI data\n");
mutex_unlock(&driver->dci_mutex);
return;
}
entry = diag_dci_get_client_entry(req_entry->client_id);
if (!entry) {
pr_err("diag: In %s, couldn't find client entry, id:%d\n",
__func__, req_entry->client_id);
mutex_unlock(&driver->dci_mutex);
return;
}
save_req_uid = req_entry->uid;
/* Remove the headers and send only the response to this function */
delete_flag = diag_dci_remove_req_entry(temp, rsp_len, req_entry);
if (delete_flag < 0) {
mutex_unlock(&driver->dci_mutex);
return;
}
mutex_lock(&entry->buffers[data_source].buf_mutex);
rsp_buf = entry->buffers[data_source].buf_cmd;
mutex_lock(&rsp_buf->data_mutex);
/*
* Check if we can fit the data in the rsp buffer. The total length of
* the rsp is the rsp length (write_len) + DCI_PKT_RSP_TYPE header (int)
* + field for length (int) + delete_flag (uint8_t)
*/
if ((rsp_buf->data_len + 9 + rsp_len) > rsp_buf->capacity) {
pr_alert("diag: create capacity for pkt rsp\n");
rsp_buf->capacity += 9 + rsp_len;
temp_buf = krealloc(rsp_buf->data, rsp_buf->capacity,
GFP_KERNEL);
if (!temp_buf) {
pr_err("diag: DCI realloc failed\n");
mutex_unlock(&rsp_buf->data_mutex);
mutex_unlock(&entry->buffers[data_source].buf_mutex);
mutex_unlock(&driver->dci_mutex);
return;
}
rsp_buf->data = temp_buf;
}
/* Fill in packet response header information */
pkt_rsp_header.type = DCI_PKT_RSP_TYPE;
/* Packet Length = Response Length + Length of uid field (int) */
pkt_rsp_header.length = rsp_len + sizeof(int);
pkt_rsp_header.delete_flag = delete_flag;
pkt_rsp_header.uid = save_req_uid;
memcpy(rsp_buf->data + rsp_buf->data_len, &pkt_rsp_header,
sizeof(struct diag_dci_pkt_rsp_header_t));
rsp_buf->data_len += sizeof(struct diag_dci_pkt_rsp_header_t);
memcpy(rsp_buf->data + rsp_buf->data_len, temp, rsp_len);
rsp_buf->data_len += rsp_len;
rsp_buf->data_source = data_source;
mutex_unlock(&rsp_buf->data_mutex);
/*
* Add directly to the list for writing responses to the
* userspace as these shouldn't be buffered and shouldn't wait
* for log and event buffers to be full
*/
dci_add_buffer_to_list(entry, rsp_buf);
mutex_unlock(&entry->buffers[data_source].buf_mutex);
mutex_unlock(&driver->dci_mutex);
}
static void copy_ext_hdr(struct diag_dci_buffer_t *data_buffer, void *ext_hdr)
{
if (!data_buffer) {
pr_err("diag: In %s, data buffer is NULL", __func__);
return;
}
*(int *)(data_buffer->data + data_buffer->data_len) =
DCI_EXT_HDR_TYPE;
data_buffer->data_len += sizeof(int);
memcpy(data_buffer->data + data_buffer->data_len, ext_hdr,
EXT_HDR_LEN);
data_buffer->data_len += EXT_HDR_LEN;
}
static void copy_dci_event(unsigned char *buf, int len,
struct diag_dci_client_tbl *client, int data_source,
void *ext_hdr)
{
struct diag_dci_buffer_t *data_buffer = NULL;
struct diag_dci_buf_peripheral_t *proc_buf = NULL;
int err = 0, total_len = 0;
if (!buf || !client) {
pr_err("diag: Invalid pointers in %s", __func__);
return;
}
total_len = sizeof(int) + len;
if (ext_hdr)
total_len += sizeof(int) + EXT_HDR_LEN;
proc_buf = &client->buffers[data_source];
mutex_lock(&proc_buf->buf_mutex);
mutex_lock(&proc_buf->health_mutex);
err = diag_dci_get_buffer(client, data_source, total_len);
if (err) {
if (err == -ENOMEM)
proc_buf->health.dropped_events++;
else
pr_err("diag: In %s, invalid packet\n", __func__);
mutex_unlock(&proc_buf->health_mutex);
mutex_unlock(&proc_buf->buf_mutex);
return;
}
data_buffer = proc_buf->buf_curr;
proc_buf->health.received_events++;
mutex_unlock(&proc_buf->health_mutex);
mutex_unlock(&proc_buf->buf_mutex);
mutex_lock(&data_buffer->data_mutex);
if (ext_hdr)
copy_ext_hdr(data_buffer, ext_hdr);
*(int *)(data_buffer->data + data_buffer->data_len) = DCI_EVENT_TYPE;
data_buffer->data_len += sizeof(int);
memcpy(data_buffer->data + data_buffer->data_len, buf, len);
data_buffer->data_len += len;
data_buffer->data_source = data_source;
mutex_unlock(&data_buffer->data_mutex);
}
void extract_dci_events(unsigned char *buf, int len, int data_source,
int token, void *ext_hdr)
{
uint16_t event_id, event_id_packet, length, temp_len;
uint8_t payload_len, payload_len_field;
uint8_t timestamp[8] = {0}, timestamp_len;
unsigned char event_data[MAX_EVENT_SIZE];
unsigned int total_event_len;
struct list_head *start, *temp;
struct diag_dci_client_tbl *entry = NULL;
length = *(uint16_t *)(buf + 1); /* total length of event series */
if (length == 0) {
pr_err("diag: Incoming dci event length is invalid\n");
return;
}
/*
* Move directly to the start of the event series. 1 byte for
* event code and 2 bytes for the length field.
* The length field indicates the total length removing the cmd_code
* and the length field. The event parsing in that case should happen
* till the end.
*/
temp_len = 3;
while (temp_len < length) {
event_id_packet = *(uint16_t *)(buf + temp_len);
event_id = event_id_packet & 0x0FFF; /* extract 12 bits */
if (event_id_packet & 0x8000) {
/* The packet has the two smallest byte of the
* timestamp
*/
timestamp_len = 2;
} else {
/* The packet has the full timestamp. The first event
* will always have full timestamp. Save it in the
* timestamp buffer and use it for subsequent events if
* necessary.
*/
timestamp_len = 8;
memcpy(timestamp, buf + temp_len + 2, timestamp_len);
}
/* 13th and 14th bit represent the payload length */
if (((event_id_packet & 0x6000) >> 13) == 3) {
payload_len_field = 1;
payload_len = *(uint8_t *)
(buf + temp_len + 2 + timestamp_len);
if (payload_len < (MAX_EVENT_SIZE - 13)) {
/* copy the payload length and the payload */
memcpy(event_data + 12, buf + temp_len + 2 +
timestamp_len, 1);
memcpy(event_data + 13, buf + temp_len + 2 +
timestamp_len + 1, payload_len);
} else {
pr_err("diag: event > %d, payload_len = %d\n",
(MAX_EVENT_SIZE - 13), payload_len);
return;
}
} else {
payload_len_field = 0;
payload_len = (event_id_packet & 0x6000) >> 13;
/* copy the payload */
memcpy(event_data + 12, buf + temp_len + 2 +
timestamp_len, payload_len);
}
/* Before copying the data to userspace, check if we are still
* within the buffer limit. This is an error case, don't count
* it towards the health statistics.
*
* Here, the offset of 2 bytes(uint16_t) is for the
* event_id_packet length
*/
temp_len += sizeof(uint16_t) + timestamp_len +
payload_len_field + payload_len;
if (temp_len > len) {
pr_err("diag: Invalid length in %s, len: %d, read: %d",
__func__, len, temp_len);
return;
}
/* 2 bytes for the event id & timestamp len is hard coded to 8,
* as individual events have full timestamp.
*/
*(uint16_t *)(event_data) = 10 +
payload_len_field + payload_len;
*(uint16_t *)(event_data + 2) = event_id_packet & 0x7FFF;
memcpy(event_data + 4, timestamp, 8);
/* 2 bytes for the event length field which is added to
* the event data.
*/
total_event_len = 2 + 10 + payload_len_field + payload_len;
/* parse through event mask tbl of each client and check mask */
mutex_lock(&driver->dci_mutex);
list_for_each_safe(start, temp, &driver->dci_client_list) {
entry = list_entry(start, struct diag_dci_client_tbl,
track);
if (entry->client_info.token != token)
continue;
if (diag_dci_query_event_mask(entry, event_id)) {
/* copy to client buffer */
copy_dci_event(event_data, total_event_len,
entry, data_source, ext_hdr);
}
}
mutex_unlock(&driver->dci_mutex);
}
}
static void copy_dci_log(unsigned char *buf, int len,
struct diag_dci_client_tbl *client, int data_source,
void *ext_hdr)
{
uint16_t log_length = 0;
struct diag_dci_buffer_t *data_buffer = NULL;
struct diag_dci_buf_peripheral_t *proc_buf = NULL;
int err = 0, total_len = 0;
if (!buf || !client) {
pr_err("diag: Invalid pointers in %s", __func__);
return;
}
log_length = *(uint16_t *)(buf + 2);
if (log_length > USHRT_MAX - 4) {
pr_err("diag: Integer overflow in %s, log_len: %d",
__func__, log_length);
return;
}
total_len = sizeof(int) + log_length;
if (ext_hdr)
total_len += sizeof(int) + EXT_HDR_LEN;
/* Check if we are within the len. The check should include the
* first 4 bytes for the Log code(2) and the length bytes (2)
*/
if ((log_length + sizeof(uint16_t) + 2) > len) {
pr_err("diag: Invalid length in %s, log_len: %d, len: %d",
__func__, log_length, len);
return;
}
proc_buf = &client->buffers[data_source];
mutex_lock(&proc_buf->buf_mutex);
mutex_lock(&proc_buf->health_mutex);
err = diag_dci_get_buffer(client, data_source, total_len);
if (err) {
if (err == -ENOMEM)
proc_buf->health.dropped_logs++;
else
pr_err("diag: In %s, invalid packet\n", __func__);
mutex_unlock(&proc_buf->health_mutex);
mutex_unlock(&proc_buf->buf_mutex);
return;
}
data_buffer = proc_buf->buf_curr;
proc_buf->health.received_logs++;
mutex_unlock(&proc_buf->health_mutex);
mutex_unlock(&proc_buf->buf_mutex);
mutex_lock(&data_buffer->data_mutex);
if (!data_buffer->data) {
mutex_unlock(&data_buffer->data_mutex);
return;
}
if (ext_hdr)
copy_ext_hdr(data_buffer, ext_hdr);
*(int *)(data_buffer->data + data_buffer->data_len) = DCI_LOG_TYPE;
data_buffer->data_len += sizeof(int);
memcpy(data_buffer->data + data_buffer->data_len, buf + sizeof(int),
log_length);
data_buffer->data_len += log_length;
data_buffer->data_source = data_source;
mutex_unlock(&data_buffer->data_mutex);
}
void extract_dci_log(unsigned char *buf, int len, int data_source, int token,
void *ext_hdr)
{
uint16_t log_code, read_bytes = 0;
struct list_head *start, *temp;
struct diag_dci_client_tbl *entry = NULL;
if (!buf) {
pr_err("diag: In %s buffer is NULL\n", __func__);
return;
}
/* The first six bytes for the incoming log packet contains
* Command code (2), the length of the packet (2) and the length
* of the log (2)
*/
log_code = *(uint16_t *)(buf + 6);
read_bytes += sizeof(uint16_t) + 6;
if (read_bytes > len) {
pr_err("diag: Invalid length in %s, len: %d, read: %d",
__func__, len, read_bytes);
return;
}
/* parse through log mask table of each client and check mask */
mutex_lock(&driver->dci_mutex);
list_for_each_safe(start, temp, &driver->dci_client_list) {
entry = list_entry(start, struct diag_dci_client_tbl, track);
if (entry->client_info.token != token)
continue;
if (diag_dci_query_log_mask(entry, log_code)) {
pr_debug("\t log code %x needed by client %d",
log_code, entry->client->tgid);
/* copy to client buffer */
copy_dci_log(buf, len, entry, data_source, ext_hdr);
}
}
mutex_unlock(&driver->dci_mutex);
}
void extract_dci_ext_pkt(unsigned char *buf, int len, int data_source,
int token)
{
uint8_t version, pkt_cmd_code = 0;
unsigned char *pkt = NULL;
if (!buf) {
pr_err("diag: In %s buffer is NULL\n", __func__);
return;
}
version = *(uint8_t *)buf + 1;
if (version < EXT_HDR_VERSION) {
pr_err("diag: %s, Extended header with invalid version: %d\n",
__func__, version);
return;
}
pkt = buf + EXT_HDR_LEN;
pkt_cmd_code = *(uint8_t *)pkt;
len -= EXT_HDR_LEN;
if (len < 0) {
pr_err("diag: %s, Invalid length len: %d\n", __func__, len);
return;
}
switch (pkt_cmd_code) {
case LOG_CMD_CODE:
extract_dci_log(pkt, len, data_source, token, buf);
break;
case EVENT_CMD_CODE:
extract_dci_events(pkt, len, data_source, token, buf);
break;
default:
pr_err("diag: %s unsupported cmd_code: %d, data_source: %d\n",
__func__, pkt_cmd_code, data_source);
return;
}
}
void diag_dci_channel_open_work(struct work_struct *work)
{
int i, j;
char dirty_bits[16];
uint8_t *client_log_mask_ptr;
uint8_t *log_mask_ptr;
int ret;
struct list_head *start, *temp;
struct diag_dci_client_tbl *entry = NULL;
/* Update apps and peripheral(s) with the dci log and event masks */
memset(dirty_bits, 0, 16 * sizeof(uint8_t));
/*
* From each log entry used by each client, determine
* which log entries in the cumulative logs that need
* to be updated on the peripheral.
*/
mutex_lock(&driver->dci_mutex);
list_for_each_safe(start, temp, &driver->dci_client_list) {
entry = list_entry(start, struct diag_dci_client_tbl, track);
if (entry->client_info.token != DCI_LOCAL_PROC)
continue;
client_log_mask_ptr = entry->dci_log_mask;
for (j = 0; j < 16; j++) {
if (*(client_log_mask_ptr+1))
dirty_bits[j] = 1;
client_log_mask_ptr += 514;
}
}
mutex_unlock(&driver->dci_mutex);
mutex_lock(&dci_log_mask_mutex);
/* Update the appropriate dirty bits in the cumulative mask */
log_mask_ptr = dci_ops_tbl[DCI_LOCAL_PROC].log_mask_composite;
for (i = 0; i < 16; i++) {
if (dirty_bits[i])
*(log_mask_ptr+1) = dirty_bits[i];
log_mask_ptr += 514;
}
mutex_unlock(&dci_log_mask_mutex);
/* Send updated mask to userspace clients */
diag_update_userspace_clients(DCI_LOG_MASKS_TYPE);
/* Send updated log mask to peripherals */
ret = dci_ops_tbl[DCI_LOCAL_PROC].send_log_mask(DCI_LOCAL_PROC);
/* Send updated event mask to userspace clients */
diag_update_userspace_clients(DCI_EVENT_MASKS_TYPE);
/* Send updated event mask to peripheral */
ret = dci_ops_tbl[DCI_LOCAL_PROC].send_event_mask(DCI_LOCAL_PROC);
}
void diag_dci_notify_client(int peripheral_mask, int data, int proc)
{
int stat = 0;
struct siginfo info;
struct list_head *start, *temp;
struct diag_dci_client_tbl *entry = NULL;
memset(&info, 0, sizeof(struct siginfo));
info.si_code = SI_QUEUE;
info.si_int = (peripheral_mask | data);
if (data == DIAG_STATUS_OPEN)
dci_ops_tbl[proc].peripheral_status |= peripheral_mask;
else
dci_ops_tbl[proc].peripheral_status &= ~peripheral_mask;
/* Notify the DCI process that the peripheral DCI Channel is up */
list_for_each_safe(start, temp, &driver->dci_client_list) {
entry = list_entry(start, struct diag_dci_client_tbl, track);
if (entry->client_info.token != proc)
continue;
if (entry->client_info.notification_list & peripheral_mask) {
info.si_signo = entry->client_info.signal_type;
if (entry->client &&
entry->tgid == entry->client->tgid) {
DIAG_LOG(DIAG_DEBUG_DCI,
"entry tgid = %d, dci client tgid = %d\n",
entry->tgid, entry->client->tgid);
stat = send_sig_info(
entry->client_info.signal_type,
&info, entry->client);
if (stat)
pr_err("diag: Err sending dci signal to client, signal data: 0x%x, stat: %d\n",
info.si_int, stat);
} else
pr_err("diag: client data is corrupted, signal data: 0x%x, stat: %d\n",
info.si_int, stat);
}
}
}
static int diag_send_dci_pkt(struct diag_cmd_reg_t *entry,
unsigned char *buf, int len, int tag)
{
int i, status = DIAG_DCI_NO_ERROR;
uint32_t write_len = 0;
struct diag_dci_pkt_header_t header;
if (!entry)
return -EIO;
if (len < 1 || len > DIAG_MAX_REQ_SIZE) {
pr_err("diag: dci: In %s, invalid length %d, max_length: %d\n",
__func__, len, (int)(DCI_REQ_BUF_SIZE - sizeof(header)));
return -EIO;
}
if ((len + sizeof(header) + sizeof(uint8_t)) > DCI_BUF_SIZE) {
pr_err("diag: dci: In %s, invalid length %d for apps_dci_buf, max_length: %d\n",
__func__, len, DIAG_MAX_REQ_SIZE);
return -EIO;
}
mutex_lock(&driver->dci_mutex);
/* prepare DCI packet */
header.start = CONTROL_CHAR;
header.version = 1;
header.len = len + sizeof(int) + sizeof(uint8_t);
header.pkt_code = DCI_PKT_RSP_CODE;
header.tag = tag;
memcpy(driver->apps_dci_buf, &header, sizeof(header));
write_len += sizeof(header);
memcpy(driver->apps_dci_buf + write_len, buf, len);
write_len += len;
*(uint8_t *)(driver->apps_dci_buf + write_len) = CONTROL_CHAR;
write_len += sizeof(uint8_t);
/* This command is registered locally on the Apps */
if (entry->proc == APPS_DATA) {
diag_update_pkt_buffer(driver->apps_dci_buf, write_len,
DCI_PKT_TYPE);
diag_update_sleeping_process(entry->pid, DCI_PKT_TYPE);
mutex_unlock(&driver->dci_mutex);
return DIAG_DCI_NO_ERROR;
}
for (i = 0; i < NUM_PERIPHERALS; i++)
if (entry->proc == i) {
status = 1;
break;
}
if (status) {
status = diag_dci_write_proc(entry->proc,
DIAG_DATA_TYPE,
driver->apps_dci_buf,
write_len);
} else {
pr_err("diag: Cannot send packet to peripheral %d",
entry->proc);
status = DIAG_DCI_SEND_DATA_FAIL;
}
mutex_unlock(&driver->dci_mutex);
return status;
}
#ifdef CONFIG_DIAGFWD_BRIDGE_CODE
unsigned char *dci_get_buffer_from_bridge(int token)
{
uint8_t retries = 0, max_retries = 3;
unsigned char *buf = NULL;
do {
buf = diagmem_alloc(driver, DIAG_MDM_BUF_SIZE,
dci_ops_tbl[token].mempool);
if (!buf) {
usleep_range(5000, 5100);
retries++;
} else
break;
} while (retries < max_retries);
return buf;
}
int diag_dci_write_bridge(int token, unsigned char *buf, int len)
{
return diagfwd_bridge_write(TOKEN_TO_BRIDGE(token), buf, len);
}
int diag_dci_write_done_bridge(int index, unsigned char *buf, int len)
{
int token = BRIDGE_TO_TOKEN(index);
if (!VALID_DCI_TOKEN(token)) {
pr_err("diag: Invalid DCI token %d in %s\n", token, __func__);
return -EINVAL;
}
diagmem_free(driver, buf, dci_ops_tbl[token].mempool);
return 0;
}
#endif
#ifdef CONFIG_DIAGFWD_BRIDGE_CODE
static int diag_send_dci_pkt_remote(unsigned char *data, int len, int tag,
int token)
{
unsigned char *buf = NULL;
struct diag_dci_header_t dci_header;
int dci_header_size = sizeof(struct diag_dci_header_t);
int ret = DIAG_DCI_NO_ERROR;
uint32_t write_len = 0;
if (!data)
return -EIO;
buf = dci_get_buffer_from_bridge(token);
if (!buf) {
pr_err("diag: In %s, unable to get dci buffers to write data\n",
__func__);
return -EAGAIN;
}
dci_header.start = CONTROL_CHAR;
dci_header.version = 1;
/*
* The Length of the DCI packet = length of the command + tag (int) +
* the command code size (uint8_t)
*/
dci_header.length = len + sizeof(int) + sizeof(uint8_t);
dci_header.cmd_code = DCI_PKT_RSP_CODE;
memcpy(buf + write_len, &dci_header, dci_header_size);
write_len += dci_header_size;
*(int *)(buf + write_len) = tag;
write_len += sizeof(int);
memcpy(buf + write_len, data, len);
write_len += len;
*(buf + write_len) = CONTROL_CHAR; /* End Terminator */
write_len += sizeof(uint8_t);
ret = diag_dci_write_bridge(token, buf, write_len);
if (ret) {
pr_err("diag: error writing dci pkt to remote proc, token: %d, err: %d\n",
token, ret);
diagmem_free(driver, buf, dci_ops_tbl[token].mempool);
} else {
ret = DIAG_DCI_NO_ERROR;
}
return ret;
}
#else
static int diag_send_dci_pkt_remote(unsigned char *data, int len, int tag,
int token)
{
return DIAG_DCI_NO_ERROR;
}
#endif
#ifdef CONFIG_DIAGFWD_BRIDGE_CODE
int diag_dci_send_handshake_pkt(int index)
{
int err = 0;
int token = BRIDGE_TO_TOKEN(index);
int write_len = 0;
struct diag_ctrl_dci_handshake_pkt ctrl_pkt;
unsigned char *buf = NULL;
struct diag_dci_header_t dci_header;
if (!VALID_DCI_TOKEN(token)) {
pr_err("diag: In %s, invalid DCI token %d\n", __func__, token);
return -EINVAL;
}
buf = dci_get_buffer_from_bridge(token);
if (!buf) {
pr_err("diag: In %s, unable to get dci buffers to write data\n",
__func__);
return -EAGAIN;
}
dci_header.start = CONTROL_CHAR;
dci_header.version = 1;
/* Include the cmd code (uint8_t) in the length */
dci_header.length = sizeof(ctrl_pkt) + sizeof(uint8_t);
dci_header.cmd_code = DCI_CONTROL_PKT_CODE;
memcpy(buf, &dci_header, sizeof(dci_header));
write_len += sizeof(dci_header);
ctrl_pkt.ctrl_pkt_id = DIAG_CTRL_MSG_DCI_HANDSHAKE_PKT;
/*
* The control packet data length accounts for the version (uint32_t)
* of the packet and the magic number (uint32_t).
*/
ctrl_pkt.ctrl_pkt_data_len = 2 * sizeof(uint32_t);
ctrl_pkt.version = 1;
ctrl_pkt.magic = DCI_MAGIC;
memcpy(buf + write_len, &ctrl_pkt, sizeof(ctrl_pkt));
write_len += sizeof(ctrl_pkt);
*(uint8_t *)(buf + write_len) = CONTROL_CHAR;
write_len += sizeof(uint8_t);
err = diag_dci_write_bridge(token, buf, write_len);
if (err) {
pr_err("diag: error writing ack packet to remote proc, token: %d, err: %d\n",
token, err);
diagmem_free(driver, buf, dci_ops_tbl[token].mempool);
return err;
}
mod_timer(&(dci_channel_status[token].wait_time),
jiffies + msecs_to_jiffies(DCI_HANDSHAKE_WAIT_TIME));
return 0;
}
#else
int diag_dci_send_handshake_pkt(int index)
{
return 0;
}
#endif
static int diag_dci_process_apps_pkt(struct diag_pkt_header_t *pkt_header,
unsigned char *req_buf, int req_len,
int tag)
{
uint8_t cmd_code, subsys_id, i, goto_download = 0;
uint8_t header_len = sizeof(struct diag_dci_pkt_header_t);
uint16_t ss_cmd_code;
uint32_t write_len = 0;
unsigned char *dest_buf = driver->apps_dci_buf;
unsigned char *payload_ptr = driver->apps_dci_buf + header_len;
struct diag_dci_pkt_header_t dci_header;
if (!pkt_header || !req_buf || req_len <= 0 || tag < 0)
return -EIO;
cmd_code = pkt_header->cmd_code;
subsys_id = pkt_header->subsys_id;
ss_cmd_code = pkt_header->subsys_cmd_code;
if (cmd_code == DIAG_CMD_DOWNLOAD) {
*payload_ptr = DIAG_CMD_DOWNLOAD;
write_len = sizeof(uint8_t);
goto_download = 1;
goto fill_buffer;
} else if (cmd_code == DIAG_CMD_VERSION) {
if (chk_polling_response()) {
for (i = 0; i < 55; i++, write_len++, payload_ptr++)
*(payload_ptr) = 0;
goto fill_buffer;
}
} else if (cmd_code == DIAG_CMD_EXT_BUILD) {
if (chk_polling_response()) {
*payload_ptr = DIAG_CMD_EXT_BUILD;
write_len = sizeof(uint8_t);
payload_ptr += sizeof(uint8_t);
for (i = 0; i < 8; i++, write_len++, payload_ptr++)
*(payload_ptr) = 0;
*(int *)(payload_ptr) = chk_config_get_id();
write_len += sizeof(int);
goto fill_buffer;
}
} else if (cmd_code == DIAG_CMD_LOG_ON_DMND) {
write_len = diag_cmd_log_on_demand(req_buf, req_len,
payload_ptr,
APPS_BUF_SIZE - header_len);
goto fill_buffer;
} else if (cmd_code != DIAG_CMD_DIAG_SUBSYS) {
return DIAG_DCI_TABLE_ERR;
}
if (subsys_id == DIAG_SS_DIAG) {
if (ss_cmd_code == DIAG_DIAG_MAX_PKT_SZ) {
memcpy(payload_ptr, pkt_header,
sizeof(struct diag_pkt_header_t));
write_len = sizeof(struct diag_pkt_header_t);
*(uint32_t *)(payload_ptr + write_len) =
DIAG_MAX_REQ_SIZE;
write_len += sizeof(uint32_t);
} else if (ss_cmd_code == DIAG_DIAG_STM) {
write_len = diag_process_stm_cmd(req_buf, payload_ptr);
}
} else if (subsys_id == DIAG_SS_PARAMS) {
if (ss_cmd_code == DIAG_DIAG_POLL) {
if (chk_polling_response()) {
memcpy(payload_ptr, pkt_header,
sizeof(struct diag_pkt_header_t));
write_len = sizeof(struct diag_pkt_header_t);
payload_ptr += write_len;
for (i = 0; i < 12; i++, write_len++) {
*(payload_ptr) = 0;
payload_ptr++;
}
}
} else if (ss_cmd_code == DIAG_DEL_RSP_WRAP) {
memcpy(payload_ptr, pkt_header,
sizeof(struct diag_pkt_header_t));
write_len = sizeof(struct diag_pkt_header_t);
*(int *)(payload_ptr + write_len) = wrap_enabled;
write_len += sizeof(int);
} else if (ss_cmd_code == DIAG_DEL_RSP_WRAP_CNT) {
wrap_enabled = true;
memcpy(payload_ptr, pkt_header,
sizeof(struct diag_pkt_header_t));
write_len = sizeof(struct diag_pkt_header_t);
*(uint16_t *)(payload_ptr + write_len) = wrap_count;
write_len += sizeof(uint16_t);
} else if (ss_cmd_code == DIAG_EXT_MOBILE_ID) {
write_len = diag_cmd_get_mobile_id(req_buf, req_len,
payload_ptr,
APPS_BUF_SIZE - header_len);
}
}
fill_buffer:
if (write_len > 0) {
/* Check if we are within the range of the buffer*/
if (write_len + header_len > DIAG_MAX_REQ_SIZE) {
pr_err("diag: In %s, invalid length %d\n", __func__,
write_len + header_len);
return -ENOMEM;
}
dci_header.start = CONTROL_CHAR;
dci_header.version = 1;
/*
* Length of the rsp pkt = actual data len + pkt rsp code
* (uint8_t) + tag (int)
*/
dci_header.len = write_len + sizeof(uint8_t) + sizeof(int);
dci_header.pkt_code = DCI_PKT_RSP_CODE;
dci_header.tag = tag;
driver->in_busy_dcipktdata = 1;
memcpy(dest_buf, &dci_header, header_len);
diag_process_apps_dci_read_data(DCI_PKT_TYPE, dest_buf + 4,
dci_header.len);
driver->in_busy_dcipktdata = 0;
if (goto_download) {
/*
* Sleep for sometime so that the response reaches the
* client. The value 5000 empirically as an optimum
* time for the response to reach the client.
*/
usleep_range(5000, 5100);
/* call download API */
msm_set_restart_mode(RESTART_DLOAD);
pr_alert("diag: download mode set, Rebooting SoC..\n");
kernel_restart(NULL);
}
return DIAG_DCI_NO_ERROR;
}
return DIAG_DCI_TABLE_ERR;
}
static int diag_process_dci_pkt_rsp(unsigned char *buf, int len)
{
int ret = DIAG_DCI_TABLE_ERR;
int common_cmd = 0;
struct diag_pkt_header_t *header = NULL;
unsigned char *temp = buf;
unsigned char *req_buf = NULL;
uint8_t retry_count = 0, max_retries = 3;
uint32_t read_len = 0, req_len = len;
struct dci_pkt_req_entry_t *req_entry = NULL;
struct diag_dci_client_tbl *dci_entry = NULL;
struct dci_pkt_req_t req_hdr;
struct diag_cmd_reg_t *reg_item;
struct diag_cmd_reg_entry_t reg_entry;
struct diag_cmd_reg_entry_t *temp_entry;
if (!buf)
return -EIO;
if (len <= sizeof(struct dci_pkt_req_t) || len > DCI_REQ_BUF_SIZE) {
pr_err("diag: dci: Invalid length %d len in %s", len, __func__);
return -EIO;
}
req_hdr = *(struct dci_pkt_req_t *)temp;
temp += sizeof(struct dci_pkt_req_t);
read_len += sizeof(struct dci_pkt_req_t);
req_len -= sizeof(struct dci_pkt_req_t);
req_buf = temp; /* Start of the Request */
header = (struct diag_pkt_header_t *)temp;
temp += sizeof(struct diag_pkt_header_t);
read_len += sizeof(struct diag_pkt_header_t);
if (read_len >= DCI_REQ_BUF_SIZE) {
pr_err("diag: dci: In %s, invalid read_len: %d\n", __func__,
read_len);
return -EIO;
}
mutex_lock(&driver->dci_mutex);
dci_entry = diag_dci_get_client_entry(req_hdr.client_id);
if (!dci_entry) {
pr_err("diag: Invalid client %d in %s\n",
req_hdr.client_id, __func__);
mutex_unlock(&driver->dci_mutex);
return DIAG_DCI_NO_REG;
}
/* Check if the command is allowed on DCI */
if (diag_dci_filter_commands(header)) {
pr_debug("diag: command not supported %d %d %d",
header->cmd_code, header->subsys_id,
header->subsys_cmd_code);
mutex_unlock(&driver->dci_mutex);
return DIAG_DCI_SEND_DATA_FAIL;
}
common_cmd = diag_check_common_cmd(header);
if (common_cmd < 0) {
pr_debug("diag: error in checking common command, %d\n",
common_cmd);
mutex_unlock(&driver->dci_mutex);
return DIAG_DCI_SEND_DATA_FAIL;
}
/*
* Previous packet is yet to be consumed by the client. Wait
* till the buffer is free.
*/
while (retry_count < max_retries) {
retry_count++;
if (driver->in_busy_dcipktdata)
usleep_range(10000, 10100);
else
break;
}
/* The buffer is still busy */
if (driver->in_busy_dcipktdata) {
pr_err("diag: In %s, apps dci buffer is still busy. Dropping packet\n",
__func__);
mutex_unlock(&driver->dci_mutex);
return -EAGAIN;
}
/* Register this new DCI packet */
req_entry = diag_register_dci_transaction(req_hdr.uid,
req_hdr.client_id);
if (!req_entry) {
pr_alert("diag: registering new DCI transaction failed\n");
mutex_unlock(&driver->dci_mutex);
return DIAG_DCI_NO_REG;
}
mutex_unlock(&driver->dci_mutex);
/*
* If the client has registered for remote data, route the packet to the
* remote processor
*/
if (dci_entry->client_info.token > 0) {
ret = diag_send_dci_pkt_remote(req_buf, req_len, req_entry->tag,
dci_entry->client_info.token);
return ret;
}
/* Check if it is a dedicated Apps command */
ret = diag_dci_process_apps_pkt(header, req_buf, req_len,
req_entry->tag);
if ((ret == DIAG_DCI_NO_ERROR && !common_cmd) || ret < 0)
return ret;
reg_entry.cmd_code = header->cmd_code;
reg_entry.subsys_id = header->subsys_id;
reg_entry.cmd_code_hi = header->subsys_cmd_code;
reg_entry.cmd_code_lo = header->subsys_cmd_code;
temp_entry = diag_cmd_search(&reg_entry, ALL_PROC);
if (temp_entry) {
reg_item = container_of(temp_entry, struct diag_cmd_reg_t,
entry);
ret = diag_send_dci_pkt(reg_item, req_buf, req_len,
req_entry->tag);
} else {
DIAG_LOG(DIAG_DEBUG_DCI, "Command not found: %02x %02x %02x\n",
reg_entry.cmd_code, reg_entry.subsys_id,
reg_entry.cmd_code_hi);
}
return ret;
}
int diag_process_dci_transaction(unsigned char *buf, int len)
{
unsigned char *temp = buf;
uint16_t log_code, item_num;
int ret = -1, found = 0, client_id = 0, client_token = 0;
int count, set_mask, num_codes, bit_index, event_id, offset = 0;
unsigned int byte_index, read_len = 0;
uint8_t equip_id, *log_mask_ptr, *head_log_mask_ptr, byte_mask;
uint8_t *event_mask_ptr;
struct diag_dci_client_tbl *dci_entry = NULL;
if (!temp) {
pr_err("diag: Invalid buffer in %s\n", __func__);
return -ENOMEM;
}
/* This is Pkt request/response transaction */
if (*(int *)temp > 0) {
return diag_process_dci_pkt_rsp(buf, len);
} else if (*(int *)temp == DCI_LOG_TYPE) {
/* Minimum length of a log mask config is 12 + 2 bytes for
* atleast one log code to be set or reset.
*/
if (len < DCI_LOG_CON_MIN_LEN || len > USER_SPACE_DATA) {
pr_err("diag: dci: Invalid length in %s\n", __func__);
return -EIO;
}
/* Extract each log code and put in client table */
temp += sizeof(int);
read_len += sizeof(int);
client_id = *(int *)temp;
temp += sizeof(int);
read_len += sizeof(int);
set_mask = *(int *)temp;
temp += sizeof(int);
read_len += sizeof(int);
num_codes = *(int *)temp;
temp += sizeof(int);
read_len += sizeof(int);
/* Find client table entry */
mutex_lock(&driver->dci_mutex);
dci_entry = diag_dci_get_client_entry(client_id);
if (!dci_entry) {
pr_err("diag: In %s, invalid client\n", __func__);
mutex_unlock(&driver->dci_mutex);
return ret;
}
client_token = dci_entry->client_info.token;
if (num_codes == 0 || (num_codes >= (USER_SPACE_DATA - 8)/2)) {
pr_err("diag: dci: Invalid number of log codes %d\n",
num_codes);
mutex_unlock(&driver->dci_mutex);
return -EIO;
}
head_log_mask_ptr = dci_entry->dci_log_mask;
if (!head_log_mask_ptr) {
pr_err("diag: dci: Invalid Log mask pointer in %s\n",
__func__);
mutex_unlock(&driver->dci_mutex);
return -ENOMEM;
}
pr_debug("diag: head of dci log mask %pK\n", head_log_mask_ptr);
count = 0; /* iterator for extracting log codes */
while (count < num_codes) {
if (read_len >= USER_SPACE_DATA) {
pr_err("diag: dci: Invalid length for log type in %s",
__func__);
mutex_unlock(&driver->dci_mutex);
return -EIO;
}
log_code = *(uint16_t *)temp;
equip_id = LOG_GET_EQUIP_ID(log_code);
item_num = LOG_GET_ITEM_NUM(log_code);
byte_index = item_num/8 + 2;
if (byte_index >= (DCI_MAX_ITEMS_PER_LOG_CODE+2)) {
pr_err("diag: dci: Log type, invalid byte index\n");
mutex_unlock(&driver->dci_mutex);
return ret;
}
byte_mask = 0x01 << (item_num % 8);
/*
* Parse through log mask table and find
* relevant range
*/
log_mask_ptr = head_log_mask_ptr;
found = 0;
offset = 0;
while (log_mask_ptr && (offset < DCI_LOG_MASK_SIZE)) {
if (*log_mask_ptr == equip_id) {
found = 1;
pr_debug("diag: find equip id = %x at %pK\n",
equip_id, log_mask_ptr);
break;
}
pr_debug("diag: did not find equip id = %x at %d\n",
equip_id, *log_mask_ptr);
log_mask_ptr += 514;
offset += 514;
}
if (!found) {
pr_err("diag: dci equip id not found\n");
mutex_unlock(&driver->dci_mutex);
return ret;
}
*(log_mask_ptr+1) = 1; /* set the dirty byte */
log_mask_ptr = log_mask_ptr + byte_index;
if (set_mask)
*log_mask_ptr |= byte_mask;
else
*log_mask_ptr &= ~byte_mask;
/* add to cumulative mask */
update_dci_cumulative_log_mask(
offset, byte_index,
byte_mask, client_token);
temp += 2;
read_len += 2;
count++;
ret = DIAG_DCI_NO_ERROR;
}
/* send updated mask to userspace clients */
if (client_token == DCI_LOCAL_PROC)
diag_update_userspace_clients(DCI_LOG_MASKS_TYPE);
/* send updated mask to peripherals */
ret = dci_ops_tbl[client_token].send_log_mask(client_token);
mutex_unlock(&driver->dci_mutex);
} else if (*(int *)temp == DCI_EVENT_TYPE) {
/* Minimum length of a event mask config is 12 + 4 bytes for
* atleast one event id to be set or reset.
*/
if (len < DCI_EVENT_CON_MIN_LEN || len > USER_SPACE_DATA) {
pr_err("diag: dci: Invalid length in %s\n", __func__);
return -EIO;
}
/* Extract each event id and put in client table */
temp += sizeof(int);
read_len += sizeof(int);
client_id = *(int *)temp;
temp += sizeof(int);
read_len += sizeof(int);
set_mask = *(int *)temp;
temp += sizeof(int);
read_len += sizeof(int);
num_codes = *(int *)temp;
temp += sizeof(int);
read_len += sizeof(int);
/* find client table entry */
mutex_lock(&driver->dci_mutex);
dci_entry = diag_dci_get_client_entry(client_id);
if (!dci_entry) {
pr_err("diag: In %s, invalid client\n", __func__);
mutex_unlock(&driver->dci_mutex);
return ret;
}
client_token = dci_entry->client_info.token;
/* Check for positive number of event ids. Also, the number of
* event ids should fit in the buffer along with set_mask and
* num_codes which are 4 bytes each.
*/
if (num_codes == 0 || (num_codes >= (USER_SPACE_DATA - 8)/2)) {
pr_err("diag: dci: Invalid number of event ids %d\n",
num_codes);
mutex_unlock(&driver->dci_mutex);
return -EIO;
}
event_mask_ptr = dci_entry->dci_event_mask;
if (!event_mask_ptr) {
pr_err("diag: dci: Invalid event mask pointer in %s\n",
__func__);
mutex_unlock(&driver->dci_mutex);
return -ENOMEM;
}
pr_debug("diag: head of dci event mask %pK\n", event_mask_ptr);
count = 0; /* iterator for extracting log codes */
while (count < num_codes) {
if (read_len >= USER_SPACE_DATA) {
pr_err("diag: dci: Invalid length for event type in %s",
__func__);
mutex_unlock(&driver->dci_mutex);
return -EIO;
}
event_id = *(int *)temp;
byte_index = event_id/8;
if (byte_index >= DCI_EVENT_MASK_SIZE) {
pr_err("diag: dci: Event type, invalid byte index\n");
mutex_unlock(&driver->dci_mutex);
return ret;
}
bit_index = event_id % 8;
byte_mask = 0x1 << bit_index;
/*
* Parse through event mask table and set
* relevant byte & bit combination
*/
if (set_mask)
*(event_mask_ptr + byte_index) |= byte_mask;
else
*(event_mask_ptr + byte_index) &= ~byte_mask;
/* add to cumulative mask */
update_dci_cumulative_event_mask(byte_index, byte_mask,
client_token);
temp += sizeof(int);
read_len += sizeof(int);
count++;
ret = DIAG_DCI_NO_ERROR;
}
/* send updated mask to userspace clients */
if (dci_entry->client_info.token == DCI_LOCAL_PROC)
diag_update_userspace_clients(DCI_EVENT_MASKS_TYPE);
/* send updated mask to peripherals */
ret = dci_ops_tbl[client_token].send_event_mask(client_token);
mutex_unlock(&driver->dci_mutex);
} else {
pr_alert("diag: Incorrect DCI transaction\n");
}
return ret;
}
struct diag_dci_client_tbl *diag_dci_get_client_entry(int client_id)
{
struct list_head *start, *temp;
struct diag_dci_client_tbl *entry = NULL;
list_for_each_safe(start, temp, &driver->dci_client_list) {
entry = list_entry(start, struct diag_dci_client_tbl, track);
if (entry->client_info.client_id == client_id)
return entry;
}
return NULL;
}
struct diag_dci_client_tbl *dci_lookup_client_entry_pid(int tgid)
{
struct list_head *start, *temp;
struct diag_dci_client_tbl *entry = NULL;
list_for_each_safe(start, temp, &driver->dci_client_list) {
entry = list_entry(start, struct diag_dci_client_tbl, track);
if (entry->client->tgid == tgid)
return entry;
}
return NULL;
}
void update_dci_cumulative_event_mask(int offset, uint8_t byte_mask, int token)
{
uint8_t *event_mask_ptr, *update_ptr = NULL;
struct list_head *start, *temp;
struct diag_dci_client_tbl *entry = NULL;
bool is_set = false;
mutex_lock(&dci_event_mask_mutex);
update_ptr = dci_ops_tbl[token].event_mask_composite;
if (!update_ptr) {
mutex_unlock(&dci_event_mask_mutex);
return;
}
update_ptr += offset;
list_for_each_safe(start, temp, &driver->dci_client_list) {
entry = list_entry(start, struct diag_dci_client_tbl, track);
if (entry->client_info.token != token)
continue;
event_mask_ptr = entry->dci_event_mask;
event_mask_ptr += offset;
if ((*event_mask_ptr & byte_mask) == byte_mask) {
is_set = true;
/* break even if one client has the event mask set */
break;
}
}
if (is_set == false)
*update_ptr &= ~byte_mask;
else
*update_ptr |= byte_mask;
mutex_unlock(&dci_event_mask_mutex);
}
void diag_dci_invalidate_cumulative_event_mask(int token)
{
int i = 0;
struct list_head *start, *temp;
struct diag_dci_client_tbl *entry = NULL;
uint8_t *event_mask_ptr, *update_ptr = NULL;
mutex_lock(&dci_event_mask_mutex);
update_ptr = dci_ops_tbl[token].event_mask_composite;
if (!update_ptr) {
mutex_unlock(&dci_event_mask_mutex);
return;
}
create_dci_event_mask_tbl(update_ptr);
list_for_each_safe(start, temp, &driver->dci_client_list) {
entry = list_entry(start, struct diag_dci_client_tbl, track);
if (entry->client_info.token != token)
continue;
event_mask_ptr = entry->dci_event_mask;
for (i = 0; i < DCI_EVENT_MASK_SIZE; i++)
*(update_ptr+i) |= *(event_mask_ptr+i);
}
mutex_unlock(&dci_event_mask_mutex);
}
#ifdef CONFIG_DIAGFWD_BRIDGE_CODE
int diag_send_dci_event_mask_remote(int token)
{
unsigned char *buf = NULL;
struct diag_dci_header_t dci_header;
struct diag_ctrl_event_mask event_mask;
int dci_header_size = sizeof(struct diag_dci_header_t);
int event_header_size = sizeof(struct diag_ctrl_event_mask);
int i, ret = DIAG_DCI_NO_ERROR, err = DIAG_DCI_NO_ERROR;
unsigned char *event_mask_ptr = NULL;
uint32_t write_len = 0;
mutex_lock(&dci_event_mask_mutex);
event_mask_ptr = dci_ops_tbl[token].event_mask_composite;
if (!event_mask_ptr) {
mutex_unlock(&dci_event_mask_mutex);
return -EINVAL;
}
buf = dci_get_buffer_from_bridge(token);
if (!buf) {
pr_err("diag: In %s, unable to get dci buffers to write data\n",
__func__);
mutex_unlock(&dci_event_mask_mutex);
return -EAGAIN;
}
/* Frame the DCI header */
dci_header.start = CONTROL_CHAR;
dci_header.version = 1;
dci_header.length = event_header_size + DCI_EVENT_MASK_SIZE + 1;
dci_header.cmd_code = DCI_CONTROL_PKT_CODE;
event_mask.cmd_type = DIAG_CTRL_MSG_EVENT_MASK;
event_mask.data_len = EVENT_MASK_CTRL_HEADER_LEN + DCI_EVENT_MASK_SIZE;
event_mask.stream_id = DCI_MASK_STREAM;
event_mask.status = DIAG_CTRL_MASK_VALID;
event_mask.event_config = 0; /* event config */
event_mask.event_mask_size = DCI_EVENT_MASK_SIZE;
for (i = 0; i < DCI_EVENT_MASK_SIZE; i++) {
if (event_mask_ptr[i] != 0) {
event_mask.event_config = 1;
break;
}
}
memcpy(buf + write_len, &dci_header, dci_header_size);
write_len += dci_header_size;
memcpy(buf + write_len, &event_mask, event_header_size);
write_len += event_header_size;
memcpy(buf + write_len, event_mask_ptr, DCI_EVENT_MASK_SIZE);
write_len += DCI_EVENT_MASK_SIZE;
*(buf + write_len) = CONTROL_CHAR; /* End Terminator */
write_len += sizeof(uint8_t);
err = diag_dci_write_bridge(token, buf, write_len);
if (err) {
pr_err("diag: error writing event mask to remote proc, token: %d, err: %d\n",
token, err);
diagmem_free(driver, buf, dci_ops_tbl[token].mempool);
ret = err;
} else {
ret = DIAG_DCI_NO_ERROR;
}
mutex_unlock(&dci_event_mask_mutex);
return ret;
}
#endif
int diag_send_dci_event_mask(int token)
{
void *buf = event_mask.update_buf;
struct diag_ctrl_event_mask header;
int header_size = sizeof(struct diag_ctrl_event_mask);
int ret = DIAG_DCI_NO_ERROR, err = DIAG_DCI_NO_ERROR, i;
unsigned char *event_mask_ptr = NULL;
mutex_lock(&dci_event_mask_mutex);
event_mask_ptr = dci_ops_tbl[DCI_LOCAL_PROC].event_mask_composite;
if (!event_mask_ptr) {
mutex_unlock(&dci_event_mask_mutex);
return -EINVAL;
}
mutex_lock(&event_mask.lock);
/* send event mask update */
header.cmd_type = DIAG_CTRL_MSG_EVENT_MASK;
header.data_len = EVENT_MASK_CTRL_HEADER_LEN + DCI_EVENT_MASK_SIZE;
header.stream_id = DCI_MASK_STREAM;
header.status = DIAG_CTRL_MASK_VALID;
header.event_config = 0; /* event config */
header.event_mask_size = DCI_EVENT_MASK_SIZE;
for (i = 0; i < DCI_EVENT_MASK_SIZE; i++) {
if (event_mask_ptr[i] != 0) {
header.event_config = 1;
break;
}
}
memcpy(buf, &header, header_size);
memcpy(buf+header_size, event_mask_ptr, DCI_EVENT_MASK_SIZE);
for (i = 0; i < NUM_PERIPHERALS; i++) {
/*
* Don't send to peripheral if its regular channel
* is down. It may also mean that the peripheral doesn't
* support DCI.
*/
err = diag_dci_write_proc(i, DIAG_CNTL_TYPE, buf,
header_size + DCI_EVENT_MASK_SIZE);
if (err != DIAG_DCI_NO_ERROR)
ret = DIAG_DCI_SEND_DATA_FAIL;
}
mutex_unlock(&event_mask.lock);
mutex_unlock(&dci_event_mask_mutex);
return ret;
}
void update_dci_cumulative_log_mask(int offset, unsigned int byte_index,
uint8_t byte_mask, int token)
{
uint8_t *log_mask_ptr, *update_ptr = NULL;
bool is_set = false;
struct list_head *start, *temp;
struct diag_dci_client_tbl *entry = NULL;
mutex_lock(&dci_log_mask_mutex);
update_ptr = dci_ops_tbl[token].log_mask_composite;
if (!update_ptr) {
mutex_unlock(&dci_log_mask_mutex);
return;
}
update_ptr += offset;
/* update the dirty bit */
*(update_ptr+1) = 1;
update_ptr = update_ptr + byte_index;
list_for_each_safe(start, temp, &driver->dci_client_list) {
entry = list_entry(start, struct diag_dci_client_tbl, track);
if (entry->client_info.token != token)
continue;
log_mask_ptr = entry->dci_log_mask;
log_mask_ptr = log_mask_ptr + offset + byte_index;
if ((*log_mask_ptr & byte_mask) == byte_mask) {
is_set = true;
/* break even if one client has the log mask set */
break;
}
}
if (is_set == false)
*update_ptr &= ~byte_mask;
else
*update_ptr |= byte_mask;
mutex_unlock(&dci_log_mask_mutex);
}
void diag_dci_invalidate_cumulative_log_mask(int token)
{
int i = 0;
struct list_head *start, *temp;
struct diag_dci_client_tbl *entry = NULL;
uint8_t *log_mask_ptr, *update_ptr = NULL;
/* Clear the composite mask and redo all the masks */
mutex_lock(&dci_log_mask_mutex);
update_ptr = dci_ops_tbl[token].log_mask_composite;
if (!update_ptr) {
mutex_unlock(&dci_log_mask_mutex);
return;
}
create_dci_log_mask_tbl(update_ptr, DCI_LOG_MASK_DIRTY);
list_for_each_safe(start, temp, &driver->dci_client_list) {
entry = list_entry(start, struct diag_dci_client_tbl, track);
if (entry->client_info.token != token)
continue;
log_mask_ptr = entry->dci_log_mask;
for (i = 0; i < DCI_LOG_MASK_SIZE; i++)
*(update_ptr+i) |= *(log_mask_ptr+i);
}
mutex_unlock(&dci_log_mask_mutex);
}
static int dci_fill_log_mask(unsigned char *dest_ptr, unsigned char *src_ptr)
{
struct diag_ctrl_log_mask header;
int header_len = sizeof(struct diag_ctrl_log_mask);
header.cmd_type = DIAG_CTRL_MSG_LOG_MASK;
header.num_items = DCI_MAX_ITEMS_PER_LOG_CODE;
header.data_len = 11 + DCI_MAX_ITEMS_PER_LOG_CODE;
header.stream_id = DCI_MASK_STREAM;
header.status = 3;
header.equip_id = *src_ptr;
header.log_mask_size = DCI_MAX_ITEMS_PER_LOG_CODE;
memcpy(dest_ptr, &header, header_len);
memcpy(dest_ptr + header_len, src_ptr + 2, DCI_MAX_ITEMS_PER_LOG_CODE);
return header_len + DCI_MAX_ITEMS_PER_LOG_CODE;
}
#ifdef CONFIG_DIAGFWD_BRIDGE_CODE
int diag_send_dci_log_mask_remote(int token)
{
unsigned char *buf = NULL;
struct diag_dci_header_t dci_header;
int dci_header_size = sizeof(struct diag_dci_header_t);
int log_header_size = sizeof(struct diag_ctrl_log_mask);
uint8_t *log_mask_ptr = NULL;
int i, ret = DIAG_DCI_NO_ERROR, err = DIAG_DCI_NO_ERROR;
int updated;
uint32_t write_len = 0;
mutex_lock(&dci_log_mask_mutex);
log_mask_ptr = dci_ops_tbl[token].log_mask_composite;
if (!log_mask_ptr) {
mutex_unlock(&dci_log_mask_mutex);
return -EINVAL;
}
/* DCI header is common to all equipment IDs */
dci_header.start = CONTROL_CHAR;
dci_header.version = 1;
dci_header.length = log_header_size + DCI_MAX_ITEMS_PER_LOG_CODE + 1;
dci_header.cmd_code = DCI_CONTROL_PKT_CODE;
for (i = 0; i < DCI_MAX_LOG_CODES; i++) {
updated = 1;
write_len = 0;
if (!*(log_mask_ptr + 1)) {
log_mask_ptr += 514;
continue;
}
buf = dci_get_buffer_from_bridge(token);
if (!buf) {
pr_err("diag: In %s, unable to get dci buffers to write data\n",
__func__);
mutex_unlock(&dci_log_mask_mutex);
return -EAGAIN;
}
memcpy(buf + write_len, &dci_header, dci_header_size);
write_len += dci_header_size;
write_len += dci_fill_log_mask(buf + write_len, log_mask_ptr);
*(buf + write_len) = CONTROL_CHAR; /* End Terminator */
write_len += sizeof(uint8_t);
err = diag_dci_write_bridge(token, buf, write_len);
if (err) {
pr_err("diag: error writing log mask to remote processor, equip_id: %d, token: %d, err: %d\n",
i, token, err);
diagmem_free(driver, buf, dci_ops_tbl[token].mempool);
updated = 0;
}
if (updated)
*(log_mask_ptr + 1) = 0; /* clear dirty byte */
log_mask_ptr += 514;
}
mutex_unlock(&dci_log_mask_mutex);
return ret;
}
#endif
int diag_send_dci_log_mask(int token)
{
void *buf = log_mask.update_buf;
int write_len = 0;
uint8_t *log_mask_ptr = NULL;
int i, j, ret = DIAG_DCI_NO_ERROR, err = DIAG_DCI_NO_ERROR;
int updated;
mutex_lock(&dci_log_mask_mutex);
log_mask_ptr = dci_ops_tbl[DCI_LOCAL_PROC].log_mask_composite;
if (!log_mask_ptr) {
mutex_unlock(&dci_log_mask_mutex);
return -EINVAL;
}
mutex_lock(&log_mask.lock);
for (i = 0; i < 16; i++) {
updated = 1;
/* Dirty bit is set don't update the mask for this equip id */
if (!(*(log_mask_ptr + 1))) {
log_mask_ptr += 514;
continue;
}
write_len = dci_fill_log_mask(buf, log_mask_ptr);
for (j = 0; j < NUM_PERIPHERALS && write_len; j++) {
err = diag_dci_write_proc(j, DIAG_CNTL_TYPE, buf,
write_len);
if (err != DIAG_DCI_NO_ERROR) {
updated = 0;
ret = DIAG_DCI_SEND_DATA_FAIL;
}
}
if (updated)
*(log_mask_ptr+1) = 0; /* clear dirty byte */
log_mask_ptr += 514;
}
mutex_unlock(&log_mask.lock);
mutex_unlock(&dci_log_mask_mutex);
return ret;
}
static int diag_dci_init_local(void)
{
struct dci_ops_tbl_t *temp = &dci_ops_tbl[DCI_LOCAL_PROC];
create_dci_log_mask_tbl(temp->log_mask_composite, DCI_LOG_MASK_CLEAN);
create_dci_event_mask_tbl(temp->event_mask_composite);
temp->peripheral_status |= DIAG_CON_APSS;
return 0;
}
#ifdef CONFIG_DIAGFWD_BRIDGE_CODE
static void diag_dci_init_handshake_remote(void)
{
int i;
struct dci_channel_status_t *temp = NULL;
for (i = DCI_REMOTE_BASE; i < NUM_DCI_PROC; i++) {
temp = &dci_channel_status[i];
temp->id = i;
setup_timer(&temp->wait_time, dci_chk_handshake, i);
INIT_WORK(&temp->handshake_work, dci_handshake_work_fn);
}
}
static int diag_dci_init_remote(void)
{
int i;
struct dci_ops_tbl_t *temp = NULL;
diagmem_init(driver, POOL_TYPE_MDM_DCI_WRITE);
for (i = DCI_REMOTE_BASE; i < DCI_REMOTE_LAST; i++) {
temp = &dci_ops_tbl[i];
create_dci_log_mask_tbl(temp->log_mask_composite,
DCI_LOG_MASK_CLEAN);
create_dci_event_mask_tbl(temp->event_mask_composite);
}
partial_pkt.data = kzalloc(MAX_DCI_PACKET_SZ, GFP_KERNEL);
if (!partial_pkt.data)
return -ENOMEM;
partial_pkt.total_len = 0;
partial_pkt.read_len = 0;
partial_pkt.remaining = 0;
partial_pkt.processing = 0;
diag_dci_init_handshake_remote();
return 0;
}
#else
static int diag_dci_init_remote(void)
{
return 0;
}
#endif
static int diag_dci_init_ops_tbl(void)
{
int err = 0;
err = diag_dci_init_local();
if (err)
goto err;
err = diag_dci_init_remote();
if (err)
goto err;
return 0;
err:
return -ENOMEM;
}
int diag_dci_init(void)
{
int ret = 0;
driver->dci_tag = 0;
driver->dci_client_id = 0;
driver->num_dci_client = 0;
mutex_init(&driver->dci_mutex);
mutex_init(&dci_log_mask_mutex);
mutex_init(&dci_event_mask_mutex);
spin_lock_init(&ws_lock);
ret = diag_dci_init_ops_tbl();
if (ret)
goto err;
if (driver->apps_dci_buf == NULL) {
driver->apps_dci_buf = kzalloc(DCI_BUF_SIZE, GFP_KERNEL);
if (driver->apps_dci_buf == NULL)
goto err;
}
INIT_LIST_HEAD(&driver->dci_client_list);
INIT_LIST_HEAD(&driver->dci_req_list);
driver->diag_dci_wq = create_singlethread_workqueue("diag_dci_wq");
if (!driver->diag_dci_wq)
goto err;
INIT_WORK(&dci_data_drain_work, dci_data_drain_work_fn);
setup_timer(&dci_drain_timer, dci_drain_data, 0);
return DIAG_DCI_NO_ERROR;
err:
pr_err("diag: Could not initialize diag DCI buffers");
kfree(driver->apps_dci_buf);
if (driver->diag_dci_wq)
destroy_workqueue(driver->diag_dci_wq);
kfree(partial_pkt.data);
mutex_destroy(&driver->dci_mutex);
mutex_destroy(&dci_log_mask_mutex);
mutex_destroy(&dci_event_mask_mutex);
return DIAG_DCI_NO_REG;
}
void diag_dci_channel_init(void)
{
uint8_t peripheral;
for (peripheral = 0; peripheral < NUM_PERIPHERALS; peripheral++) {
diagfwd_open(peripheral, TYPE_DCI);
diagfwd_open(peripheral, TYPE_DCI_CMD);
}
}
void diag_dci_exit(void)
{
kfree(partial_pkt.data);
kfree(driver->apps_dci_buf);
mutex_destroy(&driver->dci_mutex);
mutex_destroy(&dci_log_mask_mutex);
mutex_destroy(&dci_event_mask_mutex);
destroy_workqueue(driver->diag_dci_wq);
}
int diag_dci_clear_log_mask(int client_id)
{
int err = DIAG_DCI_NO_ERROR, token = DCI_LOCAL_PROC;
uint8_t *update_ptr;
struct diag_dci_client_tbl *entry = NULL;
entry = diag_dci_get_client_entry(client_id);
if (!entry) {
pr_err("diag: In %s, invalid client entry\n", __func__);
return DIAG_DCI_TABLE_ERR;
}
token = entry->client_info.token;
update_ptr = dci_ops_tbl[token].log_mask_composite;
create_dci_log_mask_tbl(entry->dci_log_mask, DCI_LOG_MASK_CLEAN);
diag_dci_invalidate_cumulative_log_mask(token);
/*
* Send updated mask to userspace clients only if the client
* is registered on the local processor
*/
if (token == DCI_LOCAL_PROC)
diag_update_userspace_clients(DCI_LOG_MASKS_TYPE);
/* Send updated mask to peripherals */
err = dci_ops_tbl[token].send_log_mask(token);
return err;
}
int diag_dci_clear_event_mask(int client_id)
{
int err = DIAG_DCI_NO_ERROR, token = DCI_LOCAL_PROC;
uint8_t *update_ptr;
struct diag_dci_client_tbl *entry = NULL;
entry = diag_dci_get_client_entry(client_id);
if (!entry) {
pr_err("diag: In %s, invalid client entry\n", __func__);
return DIAG_DCI_TABLE_ERR;
}
token = entry->client_info.token;
update_ptr = dci_ops_tbl[token].event_mask_composite;
create_dci_event_mask_tbl(entry->dci_event_mask);
diag_dci_invalidate_cumulative_event_mask(token);
/*
* Send updated mask to userspace clients only if the client is
* registerted on the local processor
*/
if (token == DCI_LOCAL_PROC)
diag_update_userspace_clients(DCI_EVENT_MASKS_TYPE);
/* Send updated mask to peripherals */
err = dci_ops_tbl[token].send_event_mask(token);
return err;
}
uint8_t diag_dci_get_cumulative_real_time(int token)
{
uint8_t real_time = MODE_NONREALTIME;
struct list_head *start, *temp;
struct diag_dci_client_tbl *entry = NULL;
list_for_each_safe(start, temp, &driver->dci_client_list) {
entry = list_entry(start, struct diag_dci_client_tbl, track);
if (entry->real_time == MODE_REALTIME &&
entry->client_info.token == token) {
real_time = 1;
break;
}
}
return real_time;
}
int diag_dci_set_real_time(struct diag_dci_client_tbl *entry, uint8_t real_time)
{
if (!entry) {
pr_err("diag: In %s, invalid client entry\n", __func__);
return 0;
}
entry->real_time = real_time;
return 1;
}
int diag_dci_register_client(struct diag_dci_reg_tbl_t *reg_entry)
{
int i, err = 0;
struct diag_dci_client_tbl *new_entry = NULL;
struct diag_dci_buf_peripheral_t *proc_buf = NULL;
if (!reg_entry)
return DIAG_DCI_NO_REG;
if (!VALID_DCI_TOKEN(reg_entry->token)) {
pr_alert("diag: Invalid DCI client token, %d\n",
reg_entry->token);
return DIAG_DCI_NO_REG;
}
if (driver->dci_state == DIAG_DCI_NO_REG)
return DIAG_DCI_NO_REG;
if (driver->num_dci_client >= MAX_DCI_CLIENTS)
return DIAG_DCI_NO_REG;
new_entry = kzalloc(sizeof(struct diag_dci_client_tbl), GFP_KERNEL);
if (!new_entry)
return DIAG_DCI_NO_REG;
mutex_lock(&driver->dci_mutex);
new_entry->client = current;
new_entry->tgid = current->tgid;
new_entry->client_info.notification_list =
reg_entry->notification_list;
new_entry->client_info.signal_type =
reg_entry->signal_type;
new_entry->client_info.token = reg_entry->token;
switch (reg_entry->token) {
case DCI_LOCAL_PROC:
new_entry->num_buffers = NUM_DCI_PERIPHERALS;
break;
case DCI_MDM_PROC:
new_entry->num_buffers = 1;
break;
}
new_entry->real_time = MODE_REALTIME;
new_entry->in_service = 0;
INIT_LIST_HEAD(&new_entry->list_write_buf);
mutex_init(&new_entry->write_buf_mutex);
new_entry->dci_log_mask = kzalloc(DCI_LOG_MASK_SIZE, GFP_KERNEL);
if (!new_entry->dci_log_mask) {
pr_err("diag: Unable to create log mask for client, %d",
driver->dci_client_id);
goto fail_alloc;
}
create_dci_log_mask_tbl(new_entry->dci_log_mask, DCI_LOG_MASK_CLEAN);
new_entry->dci_event_mask = kzalloc(DCI_EVENT_MASK_SIZE, GFP_KERNEL);
if (!new_entry->dci_event_mask)
goto fail_alloc;
create_dci_event_mask_tbl(new_entry->dci_event_mask);
new_entry->buffers = kzalloc(new_entry->num_buffers *
sizeof(struct diag_dci_buf_peripheral_t),
GFP_KERNEL);
if (!new_entry->buffers) {
pr_err("diag: Unable to allocate buffers for peripherals in %s\n",
__func__);
goto fail_alloc;
}
for (i = 0; i < new_entry->num_buffers; i++) {
proc_buf = &new_entry->buffers[i];
if (!proc_buf)
goto fail_alloc;
mutex_init(&proc_buf->health_mutex);
mutex_init(&proc_buf->buf_mutex);
proc_buf->health.dropped_events = 0;
proc_buf->health.dropped_logs = 0;
proc_buf->health.received_events = 0;
proc_buf->health.received_logs = 0;
proc_buf->buf_primary = kzalloc(
sizeof(struct diag_dci_buffer_t),
GFP_KERNEL);
if (!proc_buf->buf_primary)
goto fail_alloc;
proc_buf->buf_cmd = kzalloc(sizeof(struct diag_dci_buffer_t),
GFP_KERNEL);
if (!proc_buf->buf_cmd)
goto fail_alloc;
err = diag_dci_init_buffer(proc_buf->buf_primary,
DCI_BUF_PRIMARY);
if (err)
goto fail_alloc;
err = diag_dci_init_buffer(proc_buf->buf_cmd, DCI_BUF_CMD);
if (err)
goto fail_alloc;
proc_buf->buf_curr = proc_buf->buf_primary;
}
list_add_tail(&new_entry->track, &driver->dci_client_list);
driver->dci_client_id++;
new_entry->client_info.client_id = driver->dci_client_id;
reg_entry->client_id = driver->dci_client_id;
driver->num_dci_client++;
if (driver->num_dci_client == 1)
diag_update_proc_vote(DIAG_PROC_DCI, VOTE_UP, reg_entry->token);
queue_work(driver->diag_real_time_wq, &driver->diag_real_time_work);
mutex_unlock(&driver->dci_mutex);
return driver->dci_client_id;
fail_alloc:
if (new_entry) {
for (i = 0; i < new_entry->num_buffers; i++) {
proc_buf = &new_entry->buffers[i];
if (proc_buf) {
mutex_destroy(&proc_buf->health_mutex);
if (proc_buf->buf_primary) {
kfree(proc_buf->buf_primary->data);
mutex_destroy(
&proc_buf->buf_primary->data_mutex);
}
kfree(proc_buf->buf_primary);
if (proc_buf->buf_cmd) {
kfree(proc_buf->buf_cmd->data);
mutex_destroy(
&proc_buf->buf_cmd->data_mutex);
}
kfree(proc_buf->buf_cmd);
}
}
kfree(new_entry->dci_event_mask);
kfree(new_entry->dci_log_mask);
kfree(new_entry->buffers);
kfree(new_entry);
}
mutex_unlock(&driver->dci_mutex);
return DIAG_DCI_NO_REG;
}
int diag_dci_deinit_client(struct diag_dci_client_tbl *entry)
{
int ret = DIAG_DCI_NO_ERROR, real_time = MODE_REALTIME, i, peripheral;
struct diag_dci_buf_peripheral_t *proc_buf = NULL;
struct diag_dci_buffer_t *buf_entry, *temp;
struct list_head *start, *req_temp;
struct dci_pkt_req_entry_t *req_entry = NULL;
int token = DCI_LOCAL_PROC;
if (!entry)
return DIAG_DCI_NOT_SUPPORTED;
token = entry->client_info.token;
/*
* Remove the entry from the list before freeing the buffers
* to ensure that we don't have any invalid access.
*/
if (!list_empty(&entry->track))
list_del(&entry->track);
driver->num_dci_client--;
/*
* Clear the client's log and event masks, update the cumulative
* masks and send the masks to peripherals
*/
kfree(entry->dci_log_mask);
diag_dci_invalidate_cumulative_log_mask(token);
if (token == DCI_LOCAL_PROC)
diag_update_userspace_clients(DCI_LOG_MASKS_TYPE);
ret = dci_ops_tbl[token].send_log_mask(token);
if (ret != DIAG_DCI_NO_ERROR)
return ret;
kfree(entry->dci_event_mask);
diag_dci_invalidate_cumulative_event_mask(token);
if (token == DCI_LOCAL_PROC)
diag_update_userspace_clients(DCI_EVENT_MASKS_TYPE);
ret = dci_ops_tbl[token].send_event_mask(token);
if (ret != DIAG_DCI_NO_ERROR)
return ret;
list_for_each_safe(start, req_temp, &driver->dci_req_list) {
req_entry = list_entry(start, struct dci_pkt_req_entry_t,
track);
if (req_entry->client_id == entry->client_info.client_id) {
if (!list_empty(&req_entry->track))
list_del(&req_entry->track);
kfree(req_entry);
}
}
/* Clean up any buffer that is pending write */
mutex_lock(&entry->write_buf_mutex);
list_for_each_entry_safe(buf_entry, temp, &entry->list_write_buf,
buf_track) {
if (!list_empty(&buf_entry->buf_track))
list_del(&buf_entry->buf_track);
if (buf_entry->buf_type == DCI_BUF_SECONDARY) {
mutex_lock(&buf_entry->data_mutex);
diagmem_free(driver, buf_entry->data, POOL_TYPE_DCI);
buf_entry->data = NULL;
mutex_unlock(&buf_entry->data_mutex);
kfree(buf_entry);
} else if (buf_entry->buf_type == DCI_BUF_CMD) {
peripheral = buf_entry->data_source;
if (peripheral == APPS_DATA)
continue;
}
/*
* These are buffers that can't be written to the client which
* means that the copy cannot be completed. Make sure that we
* remove those references in DCI wakeup source.
*/
diag_ws_on_copy_fail(DIAG_WS_DCI);
}
mutex_unlock(&entry->write_buf_mutex);
for (i = 0; i < entry->num_buffers; i++) {
proc_buf = &entry->buffers[i];
buf_entry = proc_buf->buf_curr;
mutex_lock(&proc_buf->buf_mutex);
/* Clean up secondary buffer from mempool that is active */
if (buf_entry && buf_entry->buf_type == DCI_BUF_SECONDARY) {
mutex_lock(&buf_entry->data_mutex);
diagmem_free(driver, buf_entry->data, POOL_TYPE_DCI);
buf_entry->data = NULL;
mutex_unlock(&buf_entry->data_mutex);
mutex_destroy(&buf_entry->data_mutex);
kfree(buf_entry);
}
mutex_lock(&proc_buf->buf_primary->data_mutex);
kfree(proc_buf->buf_primary->data);
mutex_unlock(&proc_buf->buf_primary->data_mutex);
mutex_lock(&proc_buf->buf_cmd->data_mutex);
kfree(proc_buf->buf_cmd->data);
mutex_unlock(&proc_buf->buf_cmd->data_mutex);
mutex_destroy(&proc_buf->health_mutex);
mutex_destroy(&proc_buf->buf_primary->data_mutex);
mutex_destroy(&proc_buf->buf_cmd->data_mutex);
kfree(proc_buf->buf_primary);
kfree(proc_buf->buf_cmd);
mutex_unlock(&proc_buf->buf_mutex);
}
mutex_destroy(&entry->write_buf_mutex);
kfree(entry->buffers);
kfree(entry);
if (driver->num_dci_client == 0) {
diag_update_proc_vote(DIAG_PROC_DCI, VOTE_DOWN, token);
} else {
real_time = diag_dci_get_cumulative_real_time(token);
diag_update_real_time_vote(DIAG_PROC_DCI, real_time, token);
}
queue_work(driver->diag_real_time_wq, &driver->diag_real_time_work);
return DIAG_DCI_NO_ERROR;
}
int diag_dci_write_proc(uint8_t peripheral, int pkt_type, char *buf, int len)
{
uint8_t dest_channel = TYPE_DATA;
int err = 0;
if (!buf || peripheral >= NUM_PERIPHERALS || len < 0 ||
!(driver->feature[PERIPHERAL_MODEM].rcvd_feature_mask)) {
DIAG_LOG(DIAG_DEBUG_DCI,
"buf: 0x%pK, p: %d, len: %d, f_mask: %d\n",
buf, peripheral, len,
driver->feature[PERIPHERAL_MODEM].rcvd_feature_mask);
return -EINVAL;
}
if (pkt_type == DIAG_DATA_TYPE) {
dest_channel = TYPE_DCI_CMD;
} else if (pkt_type == DIAG_CNTL_TYPE) {
dest_channel = TYPE_CNTL;
} else {
pr_err("diag: Invalid DCI pkt type in %s", __func__);
return -EINVAL;
}
err = diagfwd_write(peripheral, dest_channel, buf, len);
if (err && err != -ENODEV) {
pr_err("diag: In %s, unable to write to peripheral: %d, type: %d, len: %d, err: %d\n",
__func__, peripheral, dest_channel, len, err);
} else {
err = DIAG_DCI_NO_ERROR;
}
return err;
}
int diag_dci_copy_health_stats(struct diag_dci_health_stats_proc *stats_proc)
{
struct diag_dci_client_tbl *entry = NULL;
struct diag_dci_health_t *health = NULL;
struct diag_dci_health_stats *stats = NULL;
int i, proc;
if (!stats_proc)
return -EINVAL;
stats = &stats_proc->health;
proc = stats_proc->proc;
if (proc < ALL_PROC || proc > APPS_DATA)
return -EINVAL;
entry = diag_dci_get_client_entry(stats_proc->client_id);
if (!entry)
return DIAG_DCI_NOT_SUPPORTED;
/*
* If the client has registered for remote processor, the
* proc field doesn't have any effect as they have only one buffer.
*/
if (entry->client_info.token)
proc = 0;
stats->stats.dropped_logs = 0;
stats->stats.dropped_events = 0;
stats->stats.received_logs = 0;
stats->stats.received_events = 0;
if (proc != ALL_PROC) {
health = &entry->buffers[proc].health;
stats->stats.dropped_logs = health->dropped_logs;
stats->stats.dropped_events = health->dropped_events;
stats->stats.received_logs = health->received_logs;
stats->stats.received_events = health->received_events;
if (stats->reset_status) {
mutex_lock(&entry->buffers[proc].health_mutex);
health->dropped_logs = 0;
health->dropped_events = 0;
health->received_logs = 0;
health->received_events = 0;
mutex_unlock(&entry->buffers[proc].health_mutex);
}
return DIAG_DCI_NO_ERROR;
}
for (i = 0; i < entry->num_buffers; i++) {
health = &entry->buffers[i].health;
stats->stats.dropped_logs += health->dropped_logs;
stats->stats.dropped_events += health->dropped_events;
stats->stats.received_logs += health->received_logs;
stats->stats.received_events += health->received_events;
if (stats->reset_status) {
mutex_lock(&entry->buffers[i].health_mutex);
health->dropped_logs = 0;
health->dropped_events = 0;
health->received_logs = 0;
health->received_events = 0;
mutex_unlock(&entry->buffers[i].health_mutex);
}
}
return DIAG_DCI_NO_ERROR;
}
int diag_dci_get_support_list(struct diag_dci_peripherals_t *support_list)
{
if (!support_list)
return -ENOMEM;
if (!VALID_DCI_TOKEN(support_list->proc))
return -EIO;
support_list->list = dci_ops_tbl[support_list->proc].peripheral_status;
return DIAG_DCI_NO_ERROR;
}