M7350/kernel/drivers/char/diag/diagfwd_peripheral.c
2024-09-09 08:57:42 +00:00

1117 lines
29 KiB
C

/* Copyright (c) 2015, 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/err.h>
#include <linux/sched.h>
#include <linux/ratelimit.h>
#include <linux/workqueue.h>
#include <linux/diagchar.h>
#include <linux/of.h>
#include <linux/kmemleak.h>
#include <linux/delay.h>
#include <linux/atomic.h>
#include "diagchar.h"
#include "diagchar_hdlc.h"
#include "diagfwd_peripheral.h"
#include "diagfwd_cntl.h"
#include "diag_masks.h"
#include "diag_dci.h"
#include "diagfwd.h"
#include "diagfwd_smd.h"
#include "diagfwd_socket.h"
#include "diag_mux.h"
#include "diag_ipc_logging.h"
struct data_header {
uint8_t control_char;
uint8_t version;
uint16_t length;
};
static struct diagfwd_info *early_init_info[NUM_TRANSPORT];
static void diagfwd_queue_read(struct diagfwd_info *fwd_info);
static void diagfwd_buffers_exit(struct diagfwd_info *fwd_info);
static void diagfwd_cntl_open(struct diagfwd_info *fwd_info);
static void diagfwd_cntl_close(struct diagfwd_info *fwd_info);
static void diagfwd_dci_open(struct diagfwd_info *fwd_info);
static void diagfwd_dci_close(struct diagfwd_info *fwd_info);
static void diagfwd_data_read_done(struct diagfwd_info *fwd_info,
unsigned char *buf, int len);
static void diagfwd_cntl_read_done(struct diagfwd_info *fwd_info,
unsigned char *buf, int len);
static void diagfwd_dci_read_done(struct diagfwd_info *fwd_info,
unsigned char *buf, int len);
struct diagfwd_info peripheral_info[NUM_TYPES][NUM_PERIPHERALS];
static struct diag_channel_ops data_ch_ops = {
.open = NULL,
.close = NULL,
.read_done = diagfwd_data_read_done
};
static struct diag_channel_ops cntl_ch_ops = {
.open = diagfwd_cntl_open,
.close = diagfwd_cntl_close,
.read_done = diagfwd_cntl_read_done
};
static struct diag_channel_ops dci_ch_ops = {
.open = diagfwd_dci_open,
.close = diagfwd_dci_close,
.read_done = diagfwd_dci_read_done
};
static void diagfwd_cntl_open(struct diagfwd_info *fwd_info)
{
if (!fwd_info)
return;
diag_cntl_channel_open(fwd_info);
}
static void diagfwd_cntl_close(struct diagfwd_info *fwd_info)
{
if (!fwd_info)
return;
diag_cntl_channel_close(fwd_info);
}
static void diagfwd_dci_open(struct diagfwd_info *fwd_info)
{
if (!fwd_info)
return;
diag_dci_notify_client(PERIPHERAL_MASK(fwd_info->peripheral),
DIAG_STATUS_OPEN, DCI_LOCAL_PROC);
}
static void diagfwd_dci_close(struct diagfwd_info *fwd_info)
{
if (!fwd_info)
return;
diag_dci_notify_client(PERIPHERAL_MASK(fwd_info->peripheral),
DIAG_STATUS_CLOSED, DCI_LOCAL_PROC);
}
static int diag_add_hdlc_encoding(unsigned char *dest_buf, int *dest_len,
unsigned char *buf, int len)
{
struct diag_send_desc_type send = { NULL, NULL, DIAG_STATE_START, 0 };
struct diag_hdlc_dest_type enc = { NULL, NULL, 0 };
struct data_header *header;
int header_size = sizeof(struct data_header);
uint8_t *end_control_char = NULL;
uint8_t *payload = NULL;
uint8_t *temp_buf = NULL;
uint8_t *temp_encode_buf = NULL;
int src_pkt_len;
int encoded_pkt_length;
int max_size;
int total_processed = 0;
int bytes_remaining;
int err = 0;
uint8_t loop_count = 0;
if (!dest_buf || !dest_len || !buf)
return -EIO;
temp_buf = buf;
temp_encode_buf = dest_buf;
bytes_remaining = *dest_len;
while (total_processed < len) {
loop_count++;
header = (struct data_header *)temp_buf;
/* Perform initial error checking */
if (header->control_char != CONTROL_CHAR ||
header->version != 1) {
err = -EINVAL;
break;
}
if (header->length >= bytes_remaining)
break;
payload = temp_buf + header_size;
end_control_char = payload + header->length;
if (*end_control_char != CONTROL_CHAR) {
err = -EINVAL;
break;
}
max_size = 2 * header->length + 3;
if (bytes_remaining < max_size) {
err = -EINVAL;
break;
}
/* Prepare for encoding the data */
send.state = DIAG_STATE_START;
send.pkt = payload;
send.last = (void *)(payload + header->length - 1);
send.terminate = 1;
enc.dest = temp_encode_buf;
enc.dest_last = (void *)(temp_encode_buf + max_size);
enc.crc = 0;
diag_hdlc_encode(&send, &enc);
/* Prepare for next packet */
src_pkt_len = (header_size + header->length + 1);
total_processed += src_pkt_len;
temp_buf += src_pkt_len;
encoded_pkt_length = (uint8_t *)enc.dest - temp_encode_buf;
bytes_remaining -= encoded_pkt_length;
temp_encode_buf = enc.dest;
}
*dest_len = (int)(temp_encode_buf - dest_buf);
return err;
}
static int check_bufsize_for_encoding(struct diagfwd_buf_t *buf, uint32_t len)
{
uint32_t max_size = 0;
unsigned char *temp_buf = NULL;
if (!buf || len == 0)
return -EINVAL;
max_size = (2 * len) + 3;
if (max_size > PERIPHERAL_BUF_SZ) {
if (max_size > MAX_PERIPHERAL_HDLC_BUF_SZ) {
pr_err("diag: In %s, max_size is going beyond limit %d\n",
__func__, max_size);
max_size = MAX_PERIPHERAL_HDLC_BUF_SZ;
}
if (buf->len < max_size) {
temp_buf = krealloc(buf->data, max_size +
APF_DIAG_PADDING,
GFP_KERNEL);
if (!temp_buf)
return -ENOMEM;
buf->data = temp_buf;
buf->len = max_size;
}
}
return buf->len;
}
static void diagfwd_data_read_done(struct diagfwd_info *fwd_info,
unsigned char *buf, int len)
{
int err = 0;
int write_len = 0;
unsigned char *write_buf = NULL;
struct diagfwd_buf_t *temp_buf = NULL;
struct diag_md_session_t *session_info = NULL;
uint8_t hdlc_disabled = 0;
if (!fwd_info || !buf || len <= 0) {
diag_ws_release();
return;
}
switch (fwd_info->type) {
case TYPE_DATA:
case TYPE_CMD:
break;
default:
pr_err_ratelimited("diag: In %s, invalid type %d for peripheral %d\n",
__func__, fwd_info->type,
fwd_info->peripheral);
diag_ws_release();
return;
}
mutex_lock(&driver->hdlc_disable_mutex);
mutex_lock(&fwd_info->data_mutex);
session_info = diag_md_session_get_peripheral(fwd_info->peripheral);
if (session_info)
hdlc_disabled = session_info->hdlc_disabled;
else
hdlc_disabled = driver->hdlc_disabled;
if (!driver->feature[fwd_info->peripheral].encode_hdlc) {
if (fwd_info->buf_1 && fwd_info->buf_1->data == buf) {
temp_buf = fwd_info->buf_1;
write_buf = fwd_info->buf_1->data;
} else if (fwd_info->buf_2 && fwd_info->buf_2->data == buf) {
temp_buf = fwd_info->buf_2;
write_buf = fwd_info->buf_2->data;
} else {
pr_err("diag: In %s, no match for buffer %p, peripheral %d, type: %d\n",
__func__, buf, fwd_info->peripheral,
fwd_info->type);
goto end;
}
write_len = len;
} else if (hdlc_disabled) {
/* The data is raw and and on APPS side HDLC is disabled */
if (fwd_info->buf_1 && fwd_info->buf_1->data_raw == buf) {
temp_buf = fwd_info->buf_1;
} else if (fwd_info->buf_2 &&
fwd_info->buf_2->data_raw == buf) {
temp_buf = fwd_info->buf_2;
} else {
pr_err("diag: In %s, no match for non encode buffer %p, peripheral %d, type: %d\n",
__func__, buf, fwd_info->peripheral,
fwd_info->type);
goto end;
}
if (len > PERIPHERAL_BUF_SZ) {
pr_err("diag: In %s, Incoming buffer too large %d, peripheral %d, type: %d\n",
__func__, len, fwd_info->peripheral,
fwd_info->type);
goto end;
}
write_len = len;
write_buf = buf;
} else {
if (fwd_info->buf_1 && fwd_info->buf_1->data_raw == buf) {
temp_buf = fwd_info->buf_1;
} else if (fwd_info->buf_2 &&
fwd_info->buf_2->data_raw == buf) {
temp_buf = fwd_info->buf_2;
} else {
pr_err("diag: In %s, no match for non encode buffer %p, peripheral %d, type: %d\n",
__func__, buf, fwd_info->peripheral,
fwd_info->type);
goto end;
}
write_len = check_bufsize_for_encoding(temp_buf, len);
if (write_len <= 0) {
pr_err("diag: error in checking buf for encoding\n");
goto end;
}
write_buf = temp_buf->data;
err = diag_add_hdlc_encoding(write_buf, &write_len, buf, len);
if (err) {
pr_err("diag: error in adding hdlc encoding\n");
goto end;
}
}
if (write_len > 0) {
err = diag_mux_write(DIAG_LOCAL_PROC, write_buf, write_len,
temp_buf->ctxt);
if (err) {
pr_err_ratelimited("diag: In %s, unable to write to mux error: %d\n",
__func__, err);
goto end;
}
}
mutex_unlock(&fwd_info->data_mutex);
mutex_unlock(&driver->hdlc_disable_mutex);
diagfwd_queue_read(fwd_info);
return;
end:
diag_ws_release();
mutex_unlock(&fwd_info->data_mutex);
mutex_unlock(&driver->hdlc_disable_mutex);
if (temp_buf) {
diagfwd_write_done(fwd_info->peripheral, fwd_info->type,
GET_BUF_NUM(temp_buf->ctxt));
}
diagfwd_queue_read(fwd_info);
return;
}
static void diagfwd_cntl_read_done(struct diagfwd_info *fwd_info,
unsigned char *buf, int len)
{
if (!fwd_info) {
diag_ws_release();
return;
}
if (fwd_info->type != TYPE_CNTL) {
pr_err("diag: In %s, invalid type %d for peripheral %d\n",
__func__, fwd_info->type, fwd_info->peripheral);
diag_ws_release();
return;
}
diag_ws_on_read(DIAG_WS_MUX, len);
diag_cntl_process_read_data(fwd_info, buf, len);
/*
* Control packets are not consumed by the clients. Mimic
* consumption by setting and clearing the wakeup source copy_count
* explicitly.
*/
diag_ws_on_copy_fail(DIAG_WS_MUX);
/* Reset the buffer in_busy value after processing the data */
if (fwd_info->buf_1)
atomic_set(&fwd_info->buf_1->in_busy, 0);
diagfwd_queue_read(fwd_info);
diagfwd_queue_read(&peripheral_info[TYPE_DATA][fwd_info->peripheral]);
diagfwd_queue_read(&peripheral_info[TYPE_CMD][fwd_info->peripheral]);
}
static void diagfwd_dci_read_done(struct diagfwd_info *fwd_info,
unsigned char *buf, int len)
{
if (!fwd_info)
return;
switch (fwd_info->type) {
case TYPE_DCI:
case TYPE_DCI_CMD:
break;
default:
pr_err("diag: In %s, invalid type %d for peripheral %d\n",
__func__, fwd_info->type, fwd_info->peripheral);
return;
}
diag_dci_process_peripheral_data(fwd_info, (void *)buf, len);
/* Reset the buffer in_busy value after processing the data */
if (fwd_info->buf_1)
atomic_set(&fwd_info->buf_1->in_busy, 0);
diagfwd_queue_read(fwd_info);
}
static void diagfwd_reset_buffers(struct diagfwd_info *fwd_info,
unsigned char *buf)
{
if (!fwd_info || !buf)
return;
if (!driver->feature[fwd_info->peripheral].encode_hdlc) {
if (fwd_info->buf_1 && fwd_info->buf_1->data == buf)
atomic_set(&fwd_info->buf_1->in_busy, 0);
else if (fwd_info->buf_2 && fwd_info->buf_2->data == buf)
atomic_set(&fwd_info->buf_2->in_busy, 0);
} else {
if (fwd_info->buf_1 && fwd_info->buf_1->data_raw == buf)
atomic_set(&fwd_info->buf_1->in_busy, 0);
else if (fwd_info->buf_2 && fwd_info->buf_2->data_raw == buf)
atomic_set(&fwd_info->buf_2->in_busy, 0);
}
}
int diagfwd_peripheral_init(void)
{
uint8_t peripheral;
uint8_t transport;
uint8_t type;
struct diagfwd_info *fwd_info = NULL;
for (transport = 0; transport < NUM_TRANSPORT; transport++) {
early_init_info[transport] = kzalloc(
sizeof(struct diagfwd_info) * NUM_PERIPHERALS,
GFP_KERNEL);
if (!early_init_info[transport])
return -ENOMEM;
kmemleak_not_leak(early_init_info[transport]);
}
for (peripheral = 0; peripheral < NUM_PERIPHERALS; peripheral++) {
for (transport = 0; transport < NUM_TRANSPORT; transport++) {
fwd_info = &early_init_info[transport][peripheral];
fwd_info->peripheral = peripheral;
fwd_info->type = TYPE_CNTL;
fwd_info->transport = transport;
fwd_info->ctxt = NULL;
fwd_info->p_ops = NULL;
fwd_info->ch_open = 0;
fwd_info->inited = 1;
fwd_info->read_bytes = 0;
fwd_info->write_bytes = 0;
spin_lock_init(&fwd_info->buf_lock);
mutex_init(&fwd_info->data_mutex);
}
}
for (peripheral = 0; peripheral < NUM_PERIPHERALS; peripheral++) {
for (type = 0; type < NUM_TYPES; type++) {
fwd_info = &peripheral_info[type][peripheral];
fwd_info->peripheral = peripheral;
fwd_info->type = type;
fwd_info->ctxt = NULL;
fwd_info->p_ops = NULL;
fwd_info->ch_open = 0;
fwd_info->read_bytes = 0;
fwd_info->write_bytes = 0;
spin_lock_init(&fwd_info->buf_lock);
mutex_init(&fwd_info->data_mutex);
/*
* This state shouldn't be set for Control channels
* during initialization. This is set when the feature
* mask is received for the first time.
*/
if (type != TYPE_CNTL)
fwd_info->inited = 1;
}
driver->diagfwd_data[peripheral] =
&peripheral_info[TYPE_DATA][peripheral];
driver->diagfwd_cntl[peripheral] =
&peripheral_info[TYPE_CNTL][peripheral];
driver->diagfwd_dci[peripheral] =
&peripheral_info[TYPE_DCI][peripheral];
driver->diagfwd_cmd[peripheral] =
&peripheral_info[TYPE_CMD][peripheral];
driver->diagfwd_dci_cmd[peripheral] =
&peripheral_info[TYPE_DCI_CMD][peripheral];
}
diag_smd_init();
if (driver->supports_sockets)
diag_socket_init();
return 0;
}
void diagfwd_peripheral_exit(void)
{
uint8_t peripheral;
uint8_t type;
struct diagfwd_info *fwd_info = NULL;
diag_smd_exit();
diag_socket_exit();
for (peripheral = 0; peripheral < NUM_PERIPHERALS; peripheral++) {
for (type = 0; type < NUM_TYPES; type++) {
fwd_info = &peripheral_info[type][peripheral];
fwd_info->ctxt = NULL;
fwd_info->p_ops = NULL;
fwd_info->ch_open = 0;
diagfwd_buffers_exit(fwd_info);
}
}
for (peripheral = 0; peripheral < NUM_PERIPHERALS; peripheral++) {
driver->diagfwd_data[peripheral] = NULL;
driver->diagfwd_cntl[peripheral] = NULL;
driver->diagfwd_dci[peripheral] = NULL;
driver->diagfwd_cmd[peripheral] = NULL;
driver->diagfwd_dci_cmd[peripheral] = NULL;
}
kfree(early_init_info);
}
int diagfwd_cntl_register(uint8_t transport, uint8_t peripheral, void *ctxt,
struct diag_peripheral_ops *ops,
struct diagfwd_info **fwd_ctxt)
{
struct diagfwd_info *fwd_info = NULL;
if (!ctxt || !ops)
return -EIO;
if (transport >= NUM_TRANSPORT || peripheral >= NUM_PERIPHERALS)
return -EINVAL;
fwd_info = &early_init_info[transport][peripheral];
*fwd_ctxt = &early_init_info[transport][peripheral];
fwd_info->ctxt = ctxt;
fwd_info->p_ops = ops;
fwd_info->c_ops = &cntl_ch_ops;
return 0;
}
int diagfwd_register(uint8_t transport, uint8_t peripheral, uint8_t type,
void *ctxt, struct diag_peripheral_ops *ops,
struct diagfwd_info **fwd_ctxt)
{
struct diagfwd_info *fwd_info = NULL;
if (peripheral >= NUM_PERIPHERALS || type >= NUM_TYPES ||
!ctxt || !ops || transport >= NUM_TRANSPORT) {
pr_err("diag: In %s, returning error\n", __func__);
return -EIO;
}
fwd_info = &peripheral_info[type][peripheral];
*fwd_ctxt = &peripheral_info[type][peripheral];
fwd_info->ctxt = ctxt;
fwd_info->p_ops = ops;
fwd_info->transport = transport;
fwd_info->ch_open = 0;
switch (type) {
case TYPE_DATA:
case TYPE_CMD:
fwd_info->c_ops = &data_ch_ops;
break;
case TYPE_DCI:
case TYPE_DCI_CMD:
fwd_info->c_ops = &dci_ch_ops;
break;
default:
pr_err("diag: In %s, invalid type: %d\n", __func__, type);
return -EINVAL;
}
if (atomic_read(&fwd_info->opened) &&
fwd_info->p_ops && fwd_info->p_ops->open) {
/*
* The registration can happen late, like in the case of
* sockets. fwd_info->opened reflects diag_state. Propogate the
* state to the peipherals.
*/
fwd_info->p_ops->open(fwd_info->ctxt);
}
return 0;
}
void diagfwd_deregister(uint8_t peripheral, uint8_t type, void *ctxt)
{
struct diagfwd_info *fwd_info = NULL;
if (peripheral >= NUM_PERIPHERALS || type >= NUM_TYPES || !ctxt)
return;
fwd_info = &peripheral_info[type][peripheral];
if (fwd_info->ctxt != ctxt) {
pr_err("diag: In %s, unable to find a match for p: %d t: %d\n",
__func__, peripheral, type);
return;
}
fwd_info->ctxt = NULL;
fwd_info->p_ops = NULL;
fwd_info->ch_open = 0;
diagfwd_buffers_exit(fwd_info);
switch (type) {
case TYPE_DATA:
driver->diagfwd_data[peripheral] = NULL;
break;
case TYPE_CNTL:
driver->diagfwd_cntl[peripheral] = NULL;
break;
case TYPE_DCI:
driver->diagfwd_dci[peripheral] = NULL;
break;
case TYPE_CMD:
driver->diagfwd_cmd[peripheral] = NULL;
break;
case TYPE_DCI_CMD:
driver->diagfwd_dci_cmd[peripheral] = NULL;
break;
}
}
void diagfwd_close_transport(uint8_t transport, uint8_t peripheral)
{
struct diagfwd_info *fwd_info = NULL;
struct diagfwd_info *dest_info = NULL;
int (*init_fn)(uint8_t) = NULL;
void (*invalidate_fn)(void *, struct diagfwd_info *) = NULL;
int (*check_channel_state)(void *) = NULL;
uint8_t transport_open = 0;
if (peripheral >= NUM_PERIPHERALS)
return;
switch (transport) {
case TRANSPORT_SMD:
transport_open = TRANSPORT_SOCKET;
init_fn = diag_socket_init_peripheral;
invalidate_fn = diag_socket_invalidate;
check_channel_state = diag_socket_check_state;
break;
case TRANSPORT_SOCKET:
transport_open = TRANSPORT_SMD;
init_fn = diag_smd_init_peripheral;
invalidate_fn = diag_smd_invalidate;
check_channel_state = diag_smd_check_state;
break;
default:
return;
}
fwd_info = &early_init_info[transport][peripheral];
if (fwd_info->p_ops && fwd_info->p_ops->close)
fwd_info->p_ops->close(fwd_info->ctxt);
fwd_info = &early_init_info[transport_open][peripheral];
dest_info = &peripheral_info[TYPE_CNTL][peripheral];
dest_info->inited = 1;
dest_info->ctxt = fwd_info->ctxt;
dest_info->p_ops = fwd_info->p_ops;
dest_info->c_ops = fwd_info->c_ops;
dest_info->ch_open = fwd_info->ch_open;
dest_info->read_bytes = fwd_info->read_bytes;
dest_info->write_bytes = fwd_info->write_bytes;
dest_info->inited = fwd_info->inited;
dest_info->buf_1 = fwd_info->buf_1;
dest_info->buf_2 = fwd_info->buf_2;
dest_info->transport = fwd_info->transport;
invalidate_fn(dest_info->ctxt, dest_info);
if (!check_channel_state(dest_info->ctxt))
diagfwd_late_open(dest_info);
diagfwd_cntl_open(dest_info);
init_fn(peripheral);
diagfwd_queue_read(&peripheral_info[TYPE_DATA][peripheral]);
diagfwd_queue_read(&peripheral_info[TYPE_CMD][peripheral]);
}
int diagfwd_write(uint8_t peripheral, uint8_t type, void *buf, int len)
{
struct diagfwd_info *fwd_info = NULL;
int err = 0;
uint8_t retry_count = 0;
uint8_t max_retries = 3;
if (peripheral >= NUM_PERIPHERALS || type >= NUM_TYPES)
return -EINVAL;
if (type == TYPE_CMD || type == TYPE_DCI_CMD) {
if (!driver->feature[peripheral].rcvd_feature_mask ||
!driver->feature[peripheral].sent_feature_mask) {
pr_debug_ratelimited("diag: In %s, feature mask for peripheral: %d not received or sent yet\n",
__func__, peripheral);
return 0;
}
if (!driver->feature[peripheral].separate_cmd_rsp)
type = (type == TYPE_CMD) ? TYPE_DATA : TYPE_DCI;
}
fwd_info = &peripheral_info[type][peripheral];
if (!fwd_info->inited || !atomic_read(&fwd_info->opened))
return -ENODEV;
if (!(fwd_info->p_ops && fwd_info->p_ops->write && fwd_info->ctxt))
return -EIO;
while (retry_count < max_retries) {
err = 0;
err = fwd_info->p_ops->write(fwd_info->ctxt, buf, len);
if (err && err != -ENODEV) {
usleep_range(100000, 101000);
retry_count++;
continue;
}
break;
}
if (!err)
fwd_info->write_bytes += len;
return err;
}
static void __diag_fwd_open(struct diagfwd_info *fwd_info)
{
if (!fwd_info)
return;
atomic_set(&fwd_info->opened, 1);
if (!fwd_info->inited)
return;
if (fwd_info->buf_1)
atomic_set(&fwd_info->buf_1->in_busy, 0);
if (fwd_info->buf_2)
atomic_set(&fwd_info->buf_2->in_busy, 0);
if (fwd_info->p_ops && fwd_info->p_ops->open)
fwd_info->p_ops->open(fwd_info->ctxt);
diagfwd_queue_read(fwd_info);
}
void diagfwd_early_open(uint8_t peripheral)
{
uint8_t transport = 0;
struct diagfwd_info *fwd_info = NULL;
if (peripheral >= NUM_PERIPHERALS)
return;
for (transport = 0; transport < NUM_TRANSPORT; transport++) {
fwd_info = &early_init_info[transport][peripheral];
__diag_fwd_open(fwd_info);
}
}
void diagfwd_open(uint8_t peripheral, uint8_t type)
{
struct diagfwd_info *fwd_info = NULL;
if (peripheral >= NUM_PERIPHERALS || type >= NUM_TYPES)
return;
fwd_info = &peripheral_info[type][peripheral];
__diag_fwd_open(fwd_info);
}
void diagfwd_late_open(struct diagfwd_info *fwd_info)
{
__diag_fwd_open(fwd_info);
}
void diagfwd_close(uint8_t peripheral, uint8_t type)
{
struct diagfwd_info *fwd_info = NULL;
if (peripheral >= NUM_PERIPHERALS || type >= NUM_TYPES)
return;
fwd_info = &peripheral_info[type][peripheral];
atomic_set(&fwd_info->opened, 0);
if (!fwd_info->inited)
return;
if (fwd_info->p_ops && fwd_info->p_ops->close)
fwd_info->p_ops->close(fwd_info->ctxt);
if (fwd_info->buf_1)
atomic_set(&fwd_info->buf_1->in_busy, 1);
/*
* Only Data channels have two buffers. Set both the buffers
* to busy on close.
*/
if (fwd_info->buf_2)
atomic_set(&fwd_info->buf_2->in_busy, 1);
}
int diagfwd_channel_open(struct diagfwd_info *fwd_info)
{
if (!fwd_info)
return -EIO;
if (!fwd_info->inited) {
pr_debug("diag: In %s, channel is not inited, p: %d, t: %d\n",
__func__, fwd_info->peripheral, fwd_info->type);
return -EINVAL;
}
if (fwd_info->ch_open) {
pr_debug("diag: In %s, channel is already open, p: %d, t: %d\n",
__func__, fwd_info->peripheral, fwd_info->type);
return 0;
}
fwd_info->ch_open = 1;
diagfwd_buffers_init(fwd_info);
if (fwd_info && fwd_info->c_ops && fwd_info->c_ops->open)
fwd_info->c_ops->open(fwd_info);
diagfwd_queue_read(fwd_info);
DIAG_LOG(DIAG_DEBUG_PERIPHERALS, "p: %d t: %d considered opened\n",
fwd_info->peripheral, fwd_info->type);
if (atomic_read(&fwd_info->opened)) {
if (fwd_info->p_ops && fwd_info->p_ops->open)
fwd_info->p_ops->open(fwd_info->ctxt);
}
return 0;
}
int diagfwd_channel_close(struct diagfwd_info *fwd_info)
{
if (!fwd_info)
return -EIO;
fwd_info->ch_open = 0;
if (fwd_info && fwd_info->c_ops && fwd_info->c_ops->close)
fwd_info->c_ops->close(fwd_info);
if (fwd_info->buf_1 && fwd_info->buf_1->data)
atomic_set(&fwd_info->buf_1->in_busy, 0);
if (fwd_info->buf_2 && fwd_info->buf_2->data)
atomic_set(&fwd_info->buf_2->in_busy, 0);
DIAG_LOG(DIAG_DEBUG_PERIPHERALS, "p: %d t: %d considered closed\n",
fwd_info->peripheral, fwd_info->type);
return 0;
}
int diagfwd_channel_read_done(struct diagfwd_info *fwd_info,
unsigned char *buf, uint32_t len)
{
if (!fwd_info) {
diag_ws_release();
return -EIO;
}
/*
* Diag peripheral layers should send len as 0 if there is any error
* in reading data from the transport. Use this information to reset the
* in_busy flags. No need to queue read in this case.
*/
if (len == 0) {
diagfwd_reset_buffers(fwd_info, buf);
diag_ws_release();
return 0;
}
if (fwd_info && fwd_info->c_ops && fwd_info->c_ops->read_done)
fwd_info->c_ops->read_done(fwd_info, buf, len);
fwd_info->read_bytes += len;
return 0;
}
void diagfwd_write_done(uint8_t peripheral, uint8_t type, int ctxt)
{
struct diagfwd_info *fwd_info = NULL;
if (peripheral >= NUM_PERIPHERALS || type >= NUM_TYPES)
return;
fwd_info = &peripheral_info[type][peripheral];
if (ctxt == 1 && fwd_info->buf_1)
atomic_set(&fwd_info->buf_1->in_busy, 0);
else if (ctxt == 2 && fwd_info->buf_2)
atomic_set(&fwd_info->buf_2->in_busy, 0);
else
pr_err("diag: In %s, invalid ctxt %d\n", __func__, ctxt);
diagfwd_queue_read(fwd_info);
}
void diagfwd_channel_read(struct diagfwd_info *fwd_info)
{
int err = 0;
uint32_t read_len = 0;
unsigned char *read_buf = NULL;
struct diagfwd_buf_t *temp_buf = NULL;
if (!fwd_info) {
diag_ws_release();
return;
}
if (!fwd_info->inited || !atomic_read(&fwd_info->opened)) {
pr_debug("diag: In %s, p: %d, t: %d, inited: %d, opened: %d ch_open: %d\n",
__func__, fwd_info->peripheral, fwd_info->type,
fwd_info->inited, atomic_read(&fwd_info->opened),
fwd_info->ch_open);
diag_ws_release();
return;
}
if (fwd_info->buf_1 && !atomic_read(&fwd_info->buf_1->in_busy)) {
temp_buf = fwd_info->buf_1;
atomic_set(&temp_buf->in_busy, 1);
if (driver->feature[fwd_info->peripheral].encode_hdlc &&
(fwd_info->type == TYPE_DATA ||
fwd_info->type == TYPE_CMD)) {
read_buf = fwd_info->buf_1->data_raw;
read_len = fwd_info->buf_1->len_raw;
} else {
read_buf = fwd_info->buf_1->data;
read_len = fwd_info->buf_1->len;
}
} else if (fwd_info->buf_2 && !atomic_read(&fwd_info->buf_2->in_busy)) {
temp_buf = fwd_info->buf_2;
atomic_set(&temp_buf->in_busy, 1);
if (driver->feature[fwd_info->peripheral].encode_hdlc &&
(fwd_info->type == TYPE_DATA ||
fwd_info->type == TYPE_CMD)) {
read_buf = fwd_info->buf_2->data_raw;
read_len = fwd_info->buf_2->len_raw;
} else {
read_buf = fwd_info->buf_2->data;
read_len = fwd_info->buf_2->len;
}
} else {
pr_debug("diag: In %s, both buffers are empty for p: %d, t: %d\n",
__func__, fwd_info->peripheral, fwd_info->type);
}
if (!read_buf) {
diag_ws_release();
return;
}
if (!(fwd_info->p_ops && fwd_info->p_ops->read && fwd_info->ctxt))
goto fail_return;
DIAG_LOG(DIAG_DEBUG_PERIPHERALS, "issued a read p: %d t: %d buf: %p\n",
fwd_info->peripheral, fwd_info->type, read_buf);
err = fwd_info->p_ops->read(fwd_info->ctxt, read_buf, read_len);
if (err)
goto fail_return;
return;
fail_return:
diag_ws_release();
atomic_set(&temp_buf->in_busy, 0);
return;
}
static void diagfwd_queue_read(struct diagfwd_info *fwd_info)
{
if (!fwd_info)
return;
if (!fwd_info->inited || !atomic_read(&fwd_info->opened)) {
pr_debug("diag: In %s, p: %d, t: %d, inited: %d, opened: %d ch_open: %d\n",
__func__, fwd_info->peripheral, fwd_info->type,
fwd_info->inited, atomic_read(&fwd_info->opened),
fwd_info->ch_open);
return;
}
/*
* Don't queue a read on the data and command channels before receiving
* the feature mask from the peripheral. We won't know which buffer to
* use - HDLC or non HDLC buffer for reading.
*/
if ((!driver->feature[fwd_info->peripheral].rcvd_feature_mask) &&
(fwd_info->type != TYPE_CNTL)) {
return;
}
if (fwd_info->p_ops && fwd_info->p_ops->queue_read && fwd_info->ctxt)
fwd_info->p_ops->queue_read(fwd_info->ctxt);
}
void diagfwd_buffers_init(struct diagfwd_info *fwd_info)
{
unsigned long flags;
if (!fwd_info)
return;
if (!fwd_info->inited) {
pr_err("diag: In %s, channel not inited, p: %d, t: %d\n",
__func__, fwd_info->peripheral, fwd_info->type);
return;
}
spin_lock_irqsave(&fwd_info->buf_lock, flags);
if (!fwd_info->buf_1) {
fwd_info->buf_1 = kzalloc(sizeof(struct diagfwd_buf_t),
GFP_ATOMIC);
if (!fwd_info->buf_1)
goto err;
kmemleak_not_leak(fwd_info->buf_1);
}
if (!fwd_info->buf_1->data) {
fwd_info->buf_1->data = kzalloc(PERIPHERAL_BUF_SZ +
APF_DIAG_PADDING,
GFP_ATOMIC);
if (!fwd_info->buf_1->data)
goto err;
fwd_info->buf_1->len = PERIPHERAL_BUF_SZ;
kmemleak_not_leak(fwd_info->buf_1->data);
fwd_info->buf_1->ctxt = SET_BUF_CTXT(fwd_info->peripheral,
fwd_info->type, 1);
}
if (fwd_info->type == TYPE_DATA) {
if (!fwd_info->buf_2) {
fwd_info->buf_2 = kzalloc(sizeof(struct diagfwd_buf_t),
GFP_ATOMIC);
if (!fwd_info->buf_2)
goto err;
kmemleak_not_leak(fwd_info->buf_2);
}
if (!fwd_info->buf_2->data) {
fwd_info->buf_2->data = kzalloc(PERIPHERAL_BUF_SZ +
APF_DIAG_PADDING,
GFP_ATOMIC);
if (!fwd_info->buf_2->data)
goto err;
fwd_info->buf_2->len = PERIPHERAL_BUF_SZ;
kmemleak_not_leak(fwd_info->buf_2->data);
fwd_info->buf_2->ctxt = SET_BUF_CTXT(
fwd_info->peripheral,
fwd_info->type, 2);
}
if (driver->supports_apps_hdlc_encoding) {
/* In support of hdlc encoding */
if (!fwd_info->buf_1->data_raw) {
fwd_info->buf_1->data_raw =
kzalloc(PERIPHERAL_BUF_SZ +
APF_DIAG_PADDING,
GFP_ATOMIC);
if (!fwd_info->buf_1->data_raw)
goto err;
fwd_info->buf_1->len_raw = PERIPHERAL_BUF_SZ;
kmemleak_not_leak(fwd_info->buf_1->data_raw);
}
if (!fwd_info->buf_2->data_raw) {
fwd_info->buf_2->data_raw =
kzalloc(PERIPHERAL_BUF_SZ +
APF_DIAG_PADDING,
GFP_ATOMIC);
if (!fwd_info->buf_2->data_raw)
goto err;
fwd_info->buf_2->len_raw = PERIPHERAL_BUF_SZ;
kmemleak_not_leak(fwd_info->buf_2->data_raw);
}
}
}
if (fwd_info->type == TYPE_CMD && driver->supports_apps_hdlc_encoding) {
/* In support of hdlc encoding */
if (!fwd_info->buf_1->data_raw) {
fwd_info->buf_1->data_raw = kzalloc(PERIPHERAL_BUF_SZ +
APF_DIAG_PADDING,
GFP_ATOMIC);
if (!fwd_info->buf_1->data_raw)
goto err;
fwd_info->buf_1->len_raw = PERIPHERAL_BUF_SZ;
kmemleak_not_leak(fwd_info->buf_1->data_raw);
}
}
spin_unlock_irqrestore(&fwd_info->buf_lock, flags);
return;
err:
spin_unlock_irqrestore(&fwd_info->buf_lock, flags);
diagfwd_buffers_exit(fwd_info);
return;
}
static void diagfwd_buffers_exit(struct diagfwd_info *fwd_info)
{
unsigned long flags;
if (!fwd_info)
return;
spin_lock_irqsave(&fwd_info->buf_lock, flags);
if (fwd_info->buf_1) {
kfree(fwd_info->buf_1->data);
fwd_info->buf_1->data = NULL;
kfree(fwd_info->buf_1->data_raw);
fwd_info->buf_1->data_raw = NULL;
kfree(fwd_info->buf_1);
fwd_info->buf_1 = NULL;
}
if (fwd_info->buf_2) {
kfree(fwd_info->buf_2->data);
fwd_info->buf_2->data = NULL;
kfree(fwd_info->buf_2->data_raw);
fwd_info->buf_2->data_raw = NULL;
kfree(fwd_info->buf_2);
fwd_info->buf_2 = NULL;
}
spin_unlock_irqrestore(&fwd_info->buf_lock, flags);
}