blob: 3a1c96b932ac32e663cd4ab682b2704751f986fb [file] [log] [blame]
/* Copyright (c) 2011-2014, 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.
*/
#ifdef CONFIG_DEBUG_FS
#include <linux/slab.h>
#include <linux/debugfs.h>
#include "diagchar.h"
#include "diagfwd.h"
#include "diagfwd_bridge.h"
#include "diagfwd_hsic.h"
#include "diagmem.h"
#include "diag_dci.h"
#define DEBUG_BUF_SIZE 4096
static struct dentry *diag_dbgfs_dent;
static int diag_dbgfs_table_index;
static int diag_dbgfs_finished;
static int diag_dbgfs_dci_data_index;
static int diag_dbgfs_dci_finished;
static ssize_t diag_dbgfs_read_status(struct file *file, char __user *ubuf,
size_t count, loff_t *ppos)
{
char *buf;
int ret;
unsigned int buf_size;
buf = kzalloc(sizeof(char) * DEBUG_BUF_SIZE, GFP_KERNEL);
if (!buf) {
pr_err("diag: %s, Error allocating memory\n", __func__);
return -ENOMEM;
}
buf_size = ksize(buf);
ret = scnprintf(buf, buf_size,
"modem ch: 0x%x\n"
"lpass ch: 0x%x\n"
"riva ch: 0x%x\n"
"dci ch: 0x%x\n"
"modem cntl_ch: 0x%x\n"
"lpass cntl_ch: 0x%x\n"
"riva cntl_ch: 0x%x\n"
"modem cmd ch: 0x%x\n"
"dci cmd ch: 0x%x\n"
"CPU Tools id: %d\n"
"Apps only: %d\n"
"Apps master: %d\n"
"Check Polling Response: %d\n"
"polling_reg_flag: %d\n"
"uses device tree: %d\n"
"supports separate cmdrsp: %d\n"
"Modem separate cmdrsp: %d\n"
"LPASS separate cmdrsp: %d\n"
"RIVA separate cmdrsp: %d\n"
"Modem in_busy_1: %d\n"
"Modem in_busy_2: %d\n"
"LPASS in_busy_1: %d\n"
"LPASS in_busy_2: %d\n"
"RIVA in_busy_1: %d\n"
"RIVA in_busy_2: %d\n"
"DCI Modem in_busy_1: %d\n"
"Modem CMD in_busy_1: %d\n"
"Modem CMD in_busy_2: %d\n"
"DCI CMD Modem in_busy_1: %d\n"
"Modem supports STM: %d\n"
"LPASS supports STM: %d\n"
"RIVA supports STM: %d\n"
"Modem STM state: %d\n"
"LPASS STM state: %d\n"
"RIVA STM state: %d\n"
"APPS STM state: %d\n"
"Modem STM requested state: %d\n"
"LPASS STM requested state: %d\n"
"RIVA STM requested state: %d\n"
"APPS STM requested state: %d\n"
"supports apps hdlc encoding: %d\n"
"Modem hdlc encoding: %d\n"
"Lpass hdlc encoding: %d\n"
"RIVA hdlc encoding: %d\n"
"Modem CMD hdlc encoding: %d\n"
"Modem DATA in_buf_1_size: %d\n"
"Modem DATA in_buf_2_size: %d\n"
"ADSP DATA in_buf_1_size: %d\n"
"ADSP DATA in_buf_2_size: %d\n"
"RIVA DATA in_buf_1_size: %d\n"
"RIVA DATA in_buf_2_size: %d\n"
"Modem DATA in_buf_1_raw_size: %d\n"
"Modem DATA in_buf_2_raw_size: %d\n"
"ADSP DATA in_buf_1_raw_size: %d\n"
"ADSP DATA in_buf_2_raw_size: %d\n"
"RIVA DATA in_buf_1_raw_size: %d\n"
"RIVA DATA in_buf_2_raw_size: %d\n"
"Modem CMD in_buf_1_size: %d\n"
"Modem CMD in_buf_1_raw_size: %d\n"
"Modem CNTL in_buf_1_size: %d\n"
"ADSP CNTL in_buf_1_size: %d\n"
"RIVA CNTL in_buf_1_size: %d\n"
"Modem DCI in_buf_1_size: %d\n"
"Modem DCI CMD in_buf_1_size: %d\n"
"Received Feature mask from Modem: %d\n"
"Received Feature mask from LPASS: %d\n"
"Received Feature mask from WCNSS: %d\n"
"logging_mode: %d\n"
"real_time_mode: %d\n",
(unsigned int)driver->smd_data[MODEM_DATA].ch,
(unsigned int)driver->smd_data[LPASS_DATA].ch,
(unsigned int)driver->smd_data[WCNSS_DATA].ch,
(unsigned int)driver->smd_dci[MODEM_DATA].ch,
(unsigned int)driver->smd_cntl[MODEM_DATA].ch,
(unsigned int)driver->smd_cntl[LPASS_DATA].ch,
(unsigned int)driver->smd_cntl[WCNSS_DATA].ch,
(unsigned int)driver->smd_cmd[MODEM_DATA].ch,
(unsigned int)driver->smd_dci_cmd[MODEM_DATA].ch,
chk_config_get_id(),
chk_apps_only(),
chk_apps_master(),
chk_polling_response(),
driver->polling_reg_flag,
driver->use_device_tree,
driver->supports_separate_cmdrsp,
driver->separate_cmdrsp[MODEM_DATA],
driver->separate_cmdrsp[LPASS_DATA],
driver->separate_cmdrsp[WCNSS_DATA],
driver->smd_data[MODEM_DATA].in_busy_1,
driver->smd_data[MODEM_DATA].in_busy_2,
driver->smd_data[LPASS_DATA].in_busy_1,
driver->smd_data[LPASS_DATA].in_busy_2,
driver->smd_data[WCNSS_DATA].in_busy_1,
driver->smd_data[WCNSS_DATA].in_busy_2,
driver->smd_dci[MODEM_DATA].in_busy_1,
driver->smd_cmd[MODEM_DATA].in_busy_1,
driver->smd_cmd[MODEM_DATA].in_busy_2,
driver->smd_dci_cmd[MODEM_DATA].in_busy_1,
driver->peripheral_supports_stm[MODEM_DATA],
driver->peripheral_supports_stm[LPASS_DATA],
driver->peripheral_supports_stm[WCNSS_DATA],
driver->stm_state[MODEM_DATA],
driver->stm_state[LPASS_DATA],
driver->stm_state[WCNSS_DATA],
driver->stm_state[APPS_DATA],
driver->stm_state_requested[MODEM_DATA],
driver->stm_state_requested[LPASS_DATA],
driver->stm_state_requested[WCNSS_DATA],
driver->stm_state_requested[APPS_DATA],
driver->supports_apps_hdlc_encoding,
driver->smd_data[MODEM_DATA].encode_hdlc,
driver->smd_data[LPASS_DATA].encode_hdlc,
driver->smd_data[WCNSS_DATA].encode_hdlc,
driver->smd_cmd[MODEM_DATA].encode_hdlc,
(unsigned int)driver->smd_data[MODEM_DATA].buf_in_1_size,
(unsigned int)driver->smd_data[MODEM_DATA].buf_in_2_size,
(unsigned int)driver->smd_data[LPASS_DATA].buf_in_1_size,
(unsigned int)driver->smd_data[LPASS_DATA].buf_in_2_size,
(unsigned int)driver->smd_data[WCNSS_DATA].buf_in_1_size,
(unsigned int)driver->smd_data[WCNSS_DATA].buf_in_2_size,
(unsigned int)driver->smd_data[MODEM_DATA].buf_in_1_raw_size,
(unsigned int)driver->smd_data[MODEM_DATA].buf_in_2_raw_size,
(unsigned int)driver->smd_data[LPASS_DATA].buf_in_1_raw_size,
(unsigned int)driver->smd_data[LPASS_DATA].buf_in_2_raw_size,
(unsigned int)driver->smd_data[WCNSS_DATA].buf_in_1_raw_size,
(unsigned int)driver->smd_data[WCNSS_DATA].buf_in_2_raw_size,
(unsigned int)driver->smd_cmd[MODEM_DATA].buf_in_1_size,
(unsigned int)driver->smd_cmd[MODEM_DATA].buf_in_1_raw_size,
(unsigned int)driver->smd_cntl[MODEM_DATA].buf_in_1_size,
(unsigned int)driver->smd_cntl[LPASS_DATA].buf_in_1_size,
(unsigned int)driver->smd_cntl[WCNSS_DATA].buf_in_1_size,
(unsigned int)driver->smd_dci[MODEM_DATA].buf_in_1_size,
(unsigned int)driver->smd_dci_cmd[MODEM_DATA].buf_in_1_size,
driver->rcvd_feature_mask[MODEM_DATA],
driver->rcvd_feature_mask[LPASS_DATA],
driver->rcvd_feature_mask[WCNSS_DATA],
driver->logging_mode,
driver->real_time_mode);
#ifdef CONFIG_DIAG_OVER_USB
ret += scnprintf(buf+ret, buf_size-ret,
"usb_connected: %d\n",
driver->usb_connected);
#endif
ret = simple_read_from_buffer(ubuf, count, ppos, buf, ret);
kfree(buf);
return ret;
}
static ssize_t diag_dbgfs_read_dcistats(struct file *file,
char __user *ubuf, size_t count, loff_t *ppos)
{
char *buf = NULL;
unsigned int bytes_remaining, bytes_written = 0;
unsigned int bytes_in_buf = 0, i = 0;
struct diag_dci_data_info *temp_data = dci_data_smd;
unsigned int buf_size;
buf_size = (DEBUG_BUF_SIZE < count) ? DEBUG_BUF_SIZE : count;
if (diag_dbgfs_dci_finished) {
diag_dbgfs_dci_finished = 0;
return 0;
}
buf = kzalloc(sizeof(char) * buf_size, GFP_KERNEL);
if (ZERO_OR_NULL_PTR(buf)) {
pr_err("diag: %s, Error allocating memory\n", __func__);
return -ENOMEM;
}
buf_size = ksize(buf);
bytes_remaining = buf_size;
if (diag_dbgfs_dci_data_index == 0) {
bytes_written =
scnprintf(buf, buf_size,
"number of clients: %d\n"
"dci proc active: %d\n"
"dci real time vote: %d\n",
driver->num_dci_client,
(driver->proc_active_mask & DIAG_PROC_DCI) ? 1 : 0,
(driver->proc_rt_vote_mask & DIAG_PROC_DCI) ? 1 : 0);
bytes_in_buf += bytes_written;
bytes_remaining -= bytes_written;
#ifdef CONFIG_DIAG_OVER_USB
bytes_written = scnprintf(buf+bytes_in_buf, bytes_remaining,
"usb_connected: %d\n",
driver->usb_connected);
bytes_in_buf += bytes_written;
bytes_remaining -= bytes_written;
#endif
if (driver->dci_device) {
bytes_written = scnprintf(buf+bytes_in_buf,
bytes_remaining,
"dci power active, relax: %lu, %lu\n",
driver->dci_device->power.wakeup->active_count,
driver->dci_device->power.wakeup->relax_count);
bytes_in_buf += bytes_written;
bytes_remaining -= bytes_written;
}
if (driver->dci_cmd_device) {
bytes_written = scnprintf(buf+bytes_in_buf,
bytes_remaining,
"dci cmd power active, relax: %lu, %lu\n",
driver->dci_cmd_device->power.wakeup->
active_count,
driver->dci_cmd_device->power.wakeup->
relax_count);
bytes_in_buf += bytes_written;
bytes_remaining -= bytes_written;
}
}
temp_data += diag_dbgfs_dci_data_index;
for (i = diag_dbgfs_dci_data_index; i < DIAG_DCI_DEBUG_CNT; i++) {
if (temp_data->iteration != 0) {
bytes_written = scnprintf(
buf + bytes_in_buf, bytes_remaining,
"i %-10ld\t"
"s %-10d\t"
"c %-10d\t"
"t %-15s\n",
temp_data->iteration,
temp_data->data_size,
temp_data->ch_type,
temp_data->time_stamp);
bytes_in_buf += bytes_written;
bytes_remaining -= bytes_written;
/* Check if there is room for another entry */
if (bytes_remaining < bytes_written)
break;
}
temp_data++;
}
diag_dbgfs_dci_data_index = (i >= DIAG_DCI_DEBUG_CNT) ? 0 : i + 1;
bytes_written = simple_read_from_buffer(ubuf, count, ppos, buf,
bytes_in_buf);
kfree(buf);
diag_dbgfs_dci_finished = 1;
return bytes_written;
}
static ssize_t diag_dbgfs_read_workpending(struct file *file,
char __user *ubuf, size_t count, loff_t *ppos)
{
char *buf;
int ret;
unsigned int buf_size;
buf = kzalloc(sizeof(char) * DEBUG_BUF_SIZE, GFP_KERNEL);
if (!buf) {
pr_err("diag: %s, Error allocating memory\n", __func__);
return -ENOMEM;
}
buf_size = ksize(buf);
ret = scnprintf(buf, buf_size,
"Pending status for work_stucts:\n"
"diag_drain_work: %d\n"
"Modem data diag_read_smd_work: %d\n"
"LPASS data diag_read_smd_work: %d\n"
"RIVA data diag_read_smd_work: %d\n"
"Modem cntl diag_read_smd_work: %d\n"
"LPASS cntl diag_read_smd_work: %d\n"
"RIVA cntl diag_read_smd_work: %d\n"
"Modem dci diag_read_smd_work: %d\n"
"Modem data diag_notify_update_smd_work: %d\n"
"LPASS data diag_notify_update_smd_work: %d\n"
"RIVA data diag_notify_update_smd_work: %d\n"
"Modem cntl diag_notify_update_smd_work: %d\n"
"LPASS cntl diag_notify_update_smd_work: %d\n"
"RIVA cntl diag_notify_update_smd_work: %d\n"
"Modem dci diag_notify_update_smd_work: %d\n",
work_pending(&(driver->diag_drain_work)),
work_pending(&(driver->smd_data[MODEM_DATA].
diag_read_smd_work)),
work_pending(&(driver->smd_data[LPASS_DATA].
diag_read_smd_work)),
work_pending(&(driver->smd_data[WCNSS_DATA].
diag_read_smd_work)),
work_pending(&(driver->smd_cntl[MODEM_DATA].
diag_read_smd_work)),
work_pending(&(driver->smd_cntl[LPASS_DATA].
diag_read_smd_work)),
work_pending(&(driver->smd_cntl[WCNSS_DATA].
diag_read_smd_work)),
work_pending(&(driver->smd_dci[MODEM_DATA].
diag_read_smd_work)),
work_pending(&(driver->smd_data[MODEM_DATA].
diag_notify_update_smd_work)),
work_pending(&(driver->smd_data[LPASS_DATA].
diag_notify_update_smd_work)),
work_pending(&(driver->smd_data[WCNSS_DATA].
diag_notify_update_smd_work)),
work_pending(&(driver->smd_cntl[MODEM_DATA].
diag_notify_update_smd_work)),
work_pending(&(driver->smd_cntl[LPASS_DATA].
diag_notify_update_smd_work)),
work_pending(&(driver->smd_cntl[WCNSS_DATA].
diag_notify_update_smd_work)),
work_pending(&(driver->smd_dci[MODEM_DATA].
diag_notify_update_smd_work)));
#ifdef CONFIG_DIAG_OVER_USB
ret += scnprintf(buf+ret, buf_size-ret,
"diag_proc_hdlc_work: %d\n"
"diag_read_work: %d\n",
work_pending(&(driver->diag_proc_hdlc_work)),
work_pending(&(driver->diag_read_work)));
#endif
ret = simple_read_from_buffer(ubuf, count, ppos, buf, ret);
kfree(buf);
return ret;
}
static ssize_t diag_dbgfs_read_table(struct file *file, char __user *ubuf,
size_t count, loff_t *ppos)
{
char *buf;
int ret = 0;
int i;
unsigned int bytes_remaining;
unsigned int bytes_in_buffer = 0;
unsigned int bytes_written;
unsigned int buf_size;
buf_size = (DEBUG_BUF_SIZE < count) ? DEBUG_BUF_SIZE : count;
if (diag_dbgfs_table_index >= diag_max_reg) {
/* Done. Reset to prepare for future requests */
diag_dbgfs_table_index = 0;
return 0;
}
buf = kzalloc(sizeof(char) * buf_size, GFP_KERNEL);
if (ZERO_OR_NULL_PTR(buf)) {
pr_err("diag: %s, Error allocating memory\n", __func__);
return -ENOMEM;
}
buf_size = ksize(buf);
bytes_remaining = buf_size;
if (diag_dbgfs_table_index == 0) {
bytes_written = scnprintf(buf+bytes_in_buffer, bytes_remaining,
"Client ids: Modem: %d, LPASS: %d, "
"WCNSS: %d, APPS: %d\n",
MODEM_DATA, LPASS_DATA, WCNSS_DATA, APPS_DATA);
bytes_in_buffer += bytes_written;
bytes_remaining -= bytes_written;
}
for (i = diag_dbgfs_table_index; i < diag_max_reg; i++) {
/* Do not process empty entries in the table */
if (driver->table[i].process_id == 0)
continue;
bytes_written = scnprintf(buf+bytes_in_buffer, bytes_remaining,
"i: %3d, cmd_code: %4x, subsys_id: %4x, "
"client: %2d, cmd_code_lo: %4x, "
"cmd_code_hi: %4x, process_id: %5d %s\n",
i,
driver->table[i].cmd_code,
driver->table[i].subsys_id,
driver->table[i].client_id,
driver->table[i].cmd_code_lo,
driver->table[i].cmd_code_hi,
driver->table[i].process_id,
(diag_find_polling_reg(i) ? "<- Polling cmd reg" : ""));
bytes_in_buffer += bytes_written;
/* Check if there is room to add another table entry */
bytes_remaining = buf_size - bytes_in_buffer;
if (bytes_remaining < bytes_written)
break;
}
diag_dbgfs_table_index = i+1;
*ppos = 0;
ret = simple_read_from_buffer(ubuf, count, ppos, buf, bytes_in_buffer);
kfree(buf);
return ret;
}
#ifdef CONFIG_DIAGFWD_BRIDGE_CODE
static ssize_t diag_dbgfs_read_mempool(struct file *file, char __user *ubuf,
size_t count, loff_t *ppos)
{
char *buf = NULL;
int ret = 0, i = 0;
unsigned int buf_size;
buf = kzalloc(sizeof(char) * DEBUG_BUF_SIZE, GFP_KERNEL);
if (ZERO_OR_NULL_PTR(buf)) {
pr_err("diag: %s, Error allocating memory\n", __func__);
return -ENOMEM;
}
buf_size = ksize(buf);
ret = scnprintf(buf, buf_size,
"POOL_TYPE_COPY: [0x%p : 0x%p] count = %d\n"
"POOL_TYPE_HDLC: [0x%p : 0x%p] count = %d\n"
"POOL_TYPE_USER: [0x%p : 0x%p] count = %d\n"
"POOL_TYPE_WRITE_STRUCT: [0x%p : 0x%p] count = %d\n",
driver->diagpool,
diag_pools_array[POOL_COPY_IDX],
driver->count,
driver->diag_hdlc_pool,
diag_pools_array[POOL_HDLC_IDX],
driver->count_hdlc_pool,
driver->diag_user_pool,
diag_pools_array[POOL_USER_IDX],
driver->count_user_pool,
driver->diag_write_struct_pool,
diag_pools_array[POOL_WRITE_STRUCT_IDX],
driver->count_write_struct_pool);
for (i = 0; i < MAX_HSIC_CH; i++) {
if (!diag_hsic[i].hsic_inited)
continue;
ret += scnprintf(buf+ret, buf_size-ret,
"POOL_TYPE_HSIC_%d: [0x%p : 0x%p] count = %d\n",
i+1,
diag_hsic[i].diag_hsic_pool,
diag_pools_array[POOL_HSIC_IDX + i],
diag_hsic[i].count_hsic_pool);
}
for (i = 0; i < MAX_HSIC_CH; i++) {
if (!diag_hsic[i].hsic_inited)
continue;
ret += scnprintf(buf+ret, buf_size-ret,
"POOL_TYPE_HSIC_%d_WRITE: [0x%p : 0x%p] count = %d\n",
i+1,
diag_hsic[i].diag_hsic_write_pool,
diag_pools_array[POOL_HSIC_WRITE_IDX + i],
diag_hsic[i].count_hsic_write_pool);
}
ret = simple_read_from_buffer(ubuf, count, ppos, buf, ret);
kfree(buf);
return ret;
}
#else
static ssize_t diag_dbgfs_read_mempool(struct file *file, char __user *ubuf,
size_t count, loff_t *ppos)
{
char *buf = NULL;
int ret = 0;
unsigned int buf_size;
buf = kzalloc(sizeof(char) * DEBUG_BUF_SIZE, GFP_KERNEL);
if (ZERO_OR_NULL_PTR(buf)) {
pr_err("diag: %s, Error allocating memory\n", __func__);
return -ENOMEM;
}
buf_size = ksize(buf);
ret = scnprintf(buf, buf_size,
"POOL_TYPE_COPY: [0x%p : 0x%p] count = %d\n"
"POOL_TYPE_HDLC: [0x%p : 0x%p] count = %d\n"
"POOL_TYPE_USER: [0x%p : 0x%p] count = %d\n"
"POOL_TYPE_WRITE_STRUCT: [0x%p : 0x%p] count = %d\n",
driver->diagpool,
diag_pools_array[POOL_COPY_IDX],
driver->count,
driver->diag_hdlc_pool,
diag_pools_array[POOL_HDLC_IDX],
driver->count_hdlc_pool,
driver->diag_user_pool,
diag_pools_array[POOL_USER_IDX],
driver->count_user_pool,
driver->diag_write_struct_pool,
diag_pools_array[POOL_WRITE_STRUCT_IDX],
driver->count_write_struct_pool);
ret = simple_read_from_buffer(ubuf, count, ppos, buf, ret);
kfree(buf);
return ret;
}
#endif
#ifdef CONFIG_DIAGFWD_BRIDGE_CODE
static ssize_t diag_dbgfs_read_bridge(struct file *file, char __user *ubuf,
size_t count, loff_t *ppos)
{
char *buf;
int ret;
int i;
unsigned int bytes_remaining;
unsigned int bytes_in_buffer = 0;
unsigned int bytes_written;
unsigned int buf_size;
int bytes_hsic_inited = 45;
int bytes_hsic_not_inited = 410;
buf_size = (DEBUG_BUF_SIZE < count) ? DEBUG_BUF_SIZE : count;
if (diag_dbgfs_finished) {
diag_dbgfs_finished = 0;
return 0;
}
buf = kzalloc(sizeof(char) * buf_size, GFP_KERNEL);
if (ZERO_OR_NULL_PTR(buf)) {
pr_err("diag: %s, Error allocating memory\n", __func__);
return -ENOMEM;
}
buf_size = ksize(buf);
bytes_remaining = buf_size;
/* Only one smux for now */
bytes_written = scnprintf(buf+bytes_in_buffer, bytes_remaining,
"Values for SMUX instance: 0\n"
"smux ch: %d\n"
"smux enabled %d\n"
"smux in busy %d\n"
"smux connected %d\n\n",
driver->lcid,
driver->diag_smux_enabled,
driver->in_busy_smux,
driver->smux_connected);
bytes_in_buffer += bytes_written;
bytes_remaining = buf_size - bytes_in_buffer;
bytes_written = scnprintf(buf+bytes_in_buffer, bytes_remaining,
"HSIC diag_disconnect_work: %d\n",
work_pending(&(driver->diag_disconnect_work)));
bytes_in_buffer += bytes_written;
bytes_remaining = buf_size - bytes_in_buffer;
for (i = 0; i < MAX_HSIC_CH; i++) {
if (diag_hsic[i].hsic_inited) {
/* Check if there is room to add another HSIC entry */
if (bytes_remaining < bytes_hsic_inited)
break;
bytes_written = scnprintf(buf+bytes_in_buffer,
bytes_remaining,
"Values for HSIC Instance: %d\n"
"hsic ch: %d\n"
"hsic_inited: %d\n"
"hsic enabled: %d\n"
"hsic_opened: %d\n"
"hsic_suspend: %d\n"
"in_busy_hsic_read_on_device: %d\n"
"in_busy_hsic_write: %d\n"
"count_hsic_pool: %d\n"
"count_hsic_write_pool: %d\n"
"diag_hsic_pool: %p\n"
"diag_hsic_write_pool: %p\n"
"HSIC write_len: %d\n"
"num_hsic_buf_tbl_entries: %d\n"
"HSIC usb_connected: %d\n"
"HSIC diag_read_work: %d\n"
"diag_read_hsic_work: %d\n"
"diag_usb_read_complete_work: %d\n\n",
i,
diag_hsic[i].hsic_ch,
diag_hsic[i].hsic_inited,
diag_hsic[i].hsic_device_enabled,
diag_hsic[i].hsic_device_opened,
diag_hsic[i].hsic_suspend,
diag_hsic[i].in_busy_hsic_read_on_device,
diag_hsic[i].in_busy_hsic_write,
diag_hsic[i].count_hsic_pool,
diag_hsic[i].count_hsic_write_pool,
diag_hsic[i].diag_hsic_pool,
diag_hsic[i].diag_hsic_write_pool,
diag_bridge[i].write_len,
diag_hsic[i].num_hsic_buf_tbl_entries,
diag_bridge[i].usb_connected,
work_pending(&(diag_bridge[i].diag_read_work)),
work_pending(&(diag_hsic[i].diag_read_hsic_work)),
work_pending(&(diag_bridge[i].usb_read_complete_work)));
if (bytes_written > bytes_hsic_inited)
bytes_hsic_inited = bytes_written;
} else {
/* Check if there is room to add another HSIC entry */
if (bytes_remaining < bytes_hsic_not_inited)
break;
bytes_written = scnprintf(buf+bytes_in_buffer,
bytes_remaining,
"HSIC Instance: %d has not been initialized\n\n",
i);
if (bytes_written > bytes_hsic_not_inited)
bytes_hsic_not_inited = bytes_written;
}
bytes_in_buffer += bytes_written;
bytes_remaining = buf_size - bytes_in_buffer;
}
*ppos = 0;
ret = simple_read_from_buffer(ubuf, count, ppos, buf, bytes_in_buffer);
diag_dbgfs_finished = 1;
kfree(buf);
return ret;
}
const struct file_operations diag_dbgfs_bridge_ops = {
.read = diag_dbgfs_read_bridge,
};
#endif
const struct file_operations diag_dbgfs_status_ops = {
.read = diag_dbgfs_read_status,
};
const struct file_operations diag_dbgfs_table_ops = {
.read = diag_dbgfs_read_table,
};
const struct file_operations diag_dbgfs_workpending_ops = {
.read = diag_dbgfs_read_workpending,
};
const struct file_operations diag_dbgfs_mempool_ops = {
.read = diag_dbgfs_read_mempool,
};
const struct file_operations diag_dbgfs_dcistats_ops = {
.read = diag_dbgfs_read_dcistats,
};
void diag_debugfs_init(void)
{
diag_dbgfs_dent = debugfs_create_dir("diag", 0);
if (IS_ERR(diag_dbgfs_dent))
return;
debugfs_create_file("status", 0444, diag_dbgfs_dent, 0,
&diag_dbgfs_status_ops);
debugfs_create_file("table", 0444, diag_dbgfs_dent, 0,
&diag_dbgfs_table_ops);
debugfs_create_file("work_pending", 0444, diag_dbgfs_dent, 0,
&diag_dbgfs_workpending_ops);
debugfs_create_file("mempool", 0444, diag_dbgfs_dent, 0,
&diag_dbgfs_mempool_ops);
debugfs_create_file("dci_stats", 0444, diag_dbgfs_dent, 0,
&diag_dbgfs_dcistats_ops);
#ifdef CONFIG_DIAGFWD_BRIDGE_CODE
debugfs_create_file("bridge", 0444, diag_dbgfs_dent, 0,
&diag_dbgfs_bridge_ops);
#endif
diag_dbgfs_table_index = 0;
diag_dbgfs_finished = 0;
diag_dbgfs_dci_data_index = 0;
diag_dbgfs_dci_finished = 0;
/* DCI related structures */
dci_data_smd = kzalloc(sizeof(struct diag_dci_data_info) *
DIAG_DCI_DEBUG_CNT, GFP_KERNEL);
if (ZERO_OR_NULL_PTR(dci_data_smd))
pr_warn("diag: could not allocate memory for dci debug info\n");
mutex_init(&dci_stat_mutex);
}
void diag_debugfs_cleanup(void)
{
if (diag_dbgfs_dent) {
debugfs_remove_recursive(diag_dbgfs_dent);
diag_dbgfs_dent = NULL;
}
kfree(dci_data_smd);
mutex_destroy(&dci_stat_mutex);
}
#else
void diag_debugfs_init(void) { }
void diag_debugfs_cleanup(void) { }
#endif