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gerrit-public.fairphone.software / kernel / msm-4.9 / refs/tags/FP3-REL-Q-3.A.0107 / . / drivers / char / rdbg.c
blob: 8612112c133b1c256522ef52f95515fa3a36d13a [file] [log] [blame]
/*
* Copyright (c) 2013-2017, 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/cdev.h>
#include <linux/device.h>
#include <linux/fs.h>
#include <linux/slab.h>
#include <linux/module.h>
#include <linux/of_gpio.h>
#include <soc/qcom/smem.h>
#include <linux/uaccess.h>
#include <linux/interrupt.h>
#define SMP2P_NUM_PROCS 16
#define MAX_RETRIES 20
#define SM_VERSION 1
#define SM_BLOCKSIZE 128
#define SMQ_MAGIC_INIT 0xFF00FF00
#define SMQ_MAGIC_PRODUCER (SMQ_MAGIC_INIT | 0x1)
#define SMQ_MAGIC_CONSUMER (SMQ_MAGIC_INIT | 0x2)
enum SMQ_STATUS {
SMQ_SUCCESS = 0,
SMQ_ENOMEMORY = -1,
SMQ_EBADPARM = -2,
SMQ_UNDERFLOW = -3,
SMQ_OVERFLOW = -4
};
enum smq_type {
PRODUCER = 1,
CONSUMER = 2,
INVALID = 3
};
struct smq_block_map {
uint32_t index_read;
uint32_t num_blocks;
uint8_t *map;
};
struct smq_node {
uint16_t index_block;
uint16_t num_blocks;
} __attribute__ ((__packed__));
struct smq_hdr {
uint8_t producer_version;
uint8_t consumer_version;
} __attribute__ ((__packed__));
struct smq_out_state {
uint32_t init;
uint32_t index_check_queue_for_reset;
uint32_t index_sent_write;
uint32_t index_free_read;
} __attribute__ ((__packed__));
struct smq_out {
struct smq_out_state s;
struct smq_node sent[1];
};
struct smq_in_state {
uint32_t init;
uint32_t index_check_queue_for_reset_ack;
uint32_t index_sent_read;
uint32_t index_free_write;
} __attribute__ ((__packed__));
struct smq_in {
struct smq_in_state s;
struct smq_node free[1];
};
struct smq {
struct smq_hdr *hdr;
struct smq_out *out;
struct smq_in *in;
uint8_t *blocks;
uint32_t num_blocks;
struct mutex *lock;
uint32_t initialized;
struct smq_block_map block_map;
enum smq_type type;
};
struct gpio_info {
int gpio_base_id;
int irq_base_id;
};
struct rdbg_data {
struct device *device;
struct completion work;
struct gpio_info in;
struct gpio_info out;
bool device_initialized;
int gpio_out_offset;
bool device_opened;
void *smem_addr;
size_t smem_size;
struct smq producer_smrb;
struct smq consumer_smrb;
struct mutex write_mutex;
};
struct rdbg_device {
struct cdev cdev;
struct class *class;
dev_t dev_no;
int num_devices;
struct rdbg_data *rdbg_data;
};
static struct rdbg_device g_rdbg_instance = {
{ {0} },
NULL,
0,
SMP2P_NUM_PROCS,
NULL
};
struct processor_specific_info {
char *name;
unsigned int smem_buffer_addr;
size_t smem_buffer_size;
};
static struct processor_specific_info proc_info[SMP2P_NUM_PROCS] = {
{0}, /*APPS*/
{"rdbg_modem", 0, 0}, /*MODEM*/
{"rdbg_adsp", SMEM_LC_DEBUGGER, 16*1024}, /*ADSP*/
{0}, /*SMP2P_RESERVED_PROC_1*/
{"rdbg_wcnss", 0, 0}, /*WCNSS*/
{"rdbg_cdsp", SMEM_LC_DEBUGGER, 16*1024}, /*CDSP*/
{NULL}, /*SMP2P_POWER_PROC*/
{NULL}, /*SMP2P_TZ_PROC*/
{NULL}, /*EMPTY*/
{NULL}, /*EMPTY*/
{NULL}, /*EMPTY*/
{NULL}, /*EMPTY*/
{NULL}, /*EMPTY*/
{NULL}, /*EMPTY*/
{NULL}, /*EMPTY*/
{NULL} /*SMP2P_REMOTE_MOCK_PROC*/
};
static int smq_blockmap_get(struct smq_block_map *block_map,
uint32_t *block_index, uint32_t n)
{
uint32_t start;
uint32_t mark = 0;
uint32_t found = 0;
uint32_t i = 0;
start = block_map->index_read;
if (n == 1) {
do {
if (!block_map->map[block_map->index_read]) {
*block_index = block_map->index_read;
block_map->map[block_map->index_read] = 1;
block_map->index_read++;
block_map->index_read %= block_map->num_blocks;
return SMQ_SUCCESS;
}
block_map->index_read++;
} while (start != (block_map->index_read %=
block_map->num_blocks));
} else {
mark = block_map->num_blocks;
do {
if (!block_map->map[block_map->index_read]) {
if (mark > block_map->index_read) {
mark = block_map->index_read;
start = block_map->index_read;
found = 0;
}
found++;
if (found == n) {
*block_index = mark;
for (i = 0; i < n; i++)
block_map->map[mark + i] =
(uint8_t)(n - i);
block_map->index_read += block_map->map
[block_map->index_read] - 1;
return SMQ_SUCCESS;
}
} else {
found = 0;
block_map->index_read += block_map->map
[block_map->index_read] - 1;
mark = block_map->num_blocks;
}
block_map->index_read++;
} while (start != (block_map->index_read %=
block_map->num_blocks));
}
return SMQ_ENOMEMORY;
}
static void smq_blockmap_put(struct smq_block_map *block_map, uint32_t i)
{
uint32_t num_blocks = block_map->map[i];
while (num_blocks--) {
block_map->map[i] = 0;
i++;
}
}
static int smq_blockmap_reset(struct smq_block_map *block_map)
{
if (!block_map->map)
return SMQ_ENOMEMORY;
memset(block_map->map, 0, block_map->num_blocks + 1);
block_map->index_read = 0;
return SMQ_SUCCESS;
}
static int smq_blockmap_ctor(struct smq_block_map *block_map,
uint32_t num_blocks)
{
if (num_blocks <= 1)
return SMQ_ENOMEMORY;
block_map->map = kcalloc(num_blocks, sizeof(uint8_t), GFP_KERNEL);
if (!block_map->map)
return SMQ_ENOMEMORY;
block_map->num_blocks = num_blocks - 1;
smq_blockmap_reset(block_map);
return SMQ_SUCCESS;
}
static void smq_blockmap_dtor(struct smq_block_map *block_map)
{
kfree(block_map->map);
block_map->map = NULL;
}
static int smq_free(struct smq *smq, void *data)
{
struct smq_node node;
uint32_t index_block;
int err = SMQ_SUCCESS;
if (smq->lock)
mutex_lock(smq->lock);
if ((smq->hdr->producer_version != SM_VERSION) &&
(smq->out->s.init != SMQ_MAGIC_PRODUCER)) {
err = SMQ_UNDERFLOW;
goto bail;
}
index_block = ((uint8_t *)data - smq->blocks) / SM_BLOCKSIZE;
if (index_block >= smq->num_blocks) {
err = SMQ_EBADPARM;
goto bail;
}
node.index_block = (uint16_t)index_block;
node.num_blocks = 0;
*((struct smq_node *)(smq->in->free + smq->in->
s.index_free_write)) = node;
smq->in->s.index_free_write = (smq->in->s.index_free_write + 1)
% smq->num_blocks;
bail:
if (smq->lock)
mutex_unlock(smq->lock);
return err;
}
static int smq_receive(struct smq *smq, void **pp, int *pnsize, int *pbmore)
{
struct smq_node *node;
int err = SMQ_SUCCESS;
int more = 0;
if ((smq->hdr->producer_version != SM_VERSION) &&
(smq->out->s.init != SMQ_MAGIC_PRODUCER))
return SMQ_UNDERFLOW;
if (smq->in->s.index_sent_read == smq->out->s.index_sent_write) {
err = SMQ_UNDERFLOW;
goto bail;
}
node = (struct smq_node *)(smq->out->sent + smq->in->s.index_sent_read);
if (node->index_block >= smq->num_blocks) {
err = SMQ_EBADPARM;
goto bail;
}
smq->in->s.index_sent_read = (smq->in->s.index_sent_read + 1)
% smq->num_blocks;
*pp = smq->blocks + (node->index_block * SM_BLOCKSIZE);
*pnsize = SM_BLOCKSIZE * node->num_blocks;
/*
* Ensure that the reads and writes are updated in the memory
* when they are done and not cached. Also, ensure that the reads
* and writes are not reordered as they are shared between two cores.
*/
rmb();
if (smq->in->s.index_sent_read != smq->out->s.index_sent_write)
more = 1;
bail:
*pbmore = more;
return err;
}
static int smq_alloc_send(struct smq *smq, const uint8_t *pcb, int nsize)
{
void *pv = 0;
int num_blocks;
uint32_t index_block = 0;
int err = SMQ_SUCCESS;
struct smq_node *node = NULL;
mutex_lock(smq->lock);
if ((smq->in->s.init == SMQ_MAGIC_CONSUMER) &&
(smq->hdr->consumer_version == SM_VERSION)) {
if (smq->out->s.index_check_queue_for_reset ==
smq->in->s.index_check_queue_for_reset_ack) {
while (smq->out->s.index_free_read !=
smq->in->s.index_free_write) {
node = (struct smq_node *)(
smq->in->free +
smq->out->s.index_free_read);
if (node->index_block >= smq->num_blocks) {
err = SMQ_EBADPARM;
goto bail;
}
smq->out->s.index_free_read =
(smq->out->s.index_free_read + 1)
% smq->num_blocks;
smq_blockmap_put(&smq->block_map,
node->index_block);
/*
* Ensure that the reads and writes are
* updated in the memory when they are done
* and not cached. Also, ensure that the reads
* and writes are not reordered as they are
* shared between two cores.
*/
rmb();
}
}
}
num_blocks = ALIGN(nsize, SM_BLOCKSIZE)/SM_BLOCKSIZE;
err = smq_blockmap_get(&smq->block_map, &index_block, num_blocks);
if (err != SMQ_SUCCESS)
goto bail;
pv = smq->blocks + (SM_BLOCKSIZE * index_block);
err = copy_from_user((void *)pv, (void *)pcb, nsize);
if (err != 0)
goto bail;
((struct smq_node *)(smq->out->sent +
smq->out->s.index_sent_write))->index_block
= (uint16_t)index_block;
((struct smq_node *)(smq->out->sent +
smq->out->s.index_sent_write))->num_blocks
= (uint16_t)num_blocks;
smq->out->s.index_sent_write = (smq->out->s.index_sent_write + 1)
% smq->num_blocks;
bail:
if (err != SMQ_SUCCESS) {
if (pv)
smq_blockmap_put(&smq->block_map, index_block);
}
mutex_unlock(smq->lock);
return err;
}
static int smq_reset_producer_queue_internal(struct smq *smq,
uint32_t reset_num)
{
int retval = 0;
uint32_t i;
if (smq->type != PRODUCER)
goto bail;
mutex_lock(smq->lock);
if (smq->out->s.index_check_queue_for_reset != reset_num) {
smq->out->s.index_check_queue_for_reset = reset_num;
for (i = 0; i < smq->num_blocks; i++)
(smq->out->sent + i)->index_block = 0xFFFF;
smq_blockmap_reset(&smq->block_map);
smq->out->s.index_sent_write = 0;
smq->out->s.index_free_read = 0;
retval = 1;
}
mutex_unlock(smq->lock);
bail:
return retval;
}
static int smq_check_queue_reset(struct smq *p_cons, struct smq *p_prod)
{
int retval = 0;
uint32_t reset_num, i;
if ((p_cons->type != CONSUMER) ||
(p_cons->out->s.init != SMQ_MAGIC_PRODUCER) ||
(p_cons->hdr->producer_version != SM_VERSION))
goto bail;
reset_num = p_cons->out->s.index_check_queue_for_reset;
if (p_cons->in->s.index_check_queue_for_reset_ack != reset_num) {
p_cons->in->s.index_check_queue_for_reset_ack = reset_num;
for (i = 0; i < p_cons->num_blocks; i++)
(p_cons->in->free + i)->index_block = 0xFFFF;
p_cons->in->s.index_sent_read = 0;
p_cons->in->s.index_free_write = 0;
retval = smq_reset_producer_queue_internal(p_prod, reset_num);
}
bail:
return retval;
}
static int check_subsystem_debug_enabled(void *base_addr, int size)
{
int num_blocks;
uint8_t *pb_orig;
uint8_t *pb;
struct smq smq;
int err = 0;
pb = pb_orig = (uint8_t *)base_addr;
pb += sizeof(struct smq_hdr);
pb = PTR_ALIGN(pb, 8);
size -= pb - (uint8_t *)pb_orig;
num_blocks = (int)((size - sizeof(struct smq_out_state) -
sizeof(struct smq_in_state))/(SM_BLOCKSIZE +
sizeof(struct smq_node) * 2));
if (num_blocks <= 0) {
err = SMQ_EBADPARM;
goto bail;
}
pb += num_blocks * SM_BLOCKSIZE;
smq.out = (struct smq_out *)pb;
pb += sizeof(struct smq_out_state) + (num_blocks *
sizeof(struct smq_node));
smq.in = (struct smq_in *)pb;
if (smq.in->s.init != SMQ_MAGIC_CONSUMER) {
pr_err("%s, smq in consumer not initialized", __func__);
err = -ECOMM;
}
bail:
return err;
}
static void smq_dtor(struct smq *smq)
{
if (smq->initialized == SMQ_MAGIC_INIT) {
switch (smq->type) {
case PRODUCER:
smq->out->s.init = 0;
smq_blockmap_dtor(&smq->block_map);
break;
case CONSUMER:
smq->in->s.init = 0;
break;
default:
case INVALID:
break;
}
smq->initialized = 0;
}
}
/*
* The shared memory is used as a circular ring buffer in each direction.
* Thus we have a bi-directional shared memory channel between the AP
* and a subsystem. We call this SMQ. Each memory channel contains a header,
* data and a control mechanism that is used to synchronize read and write
* of data between the AP and the remote subsystem.
*
* Overall SMQ memory view:
*
* +------------------------------------------------+
* | SMEM buffer |
* |-----------------------+------------------------|
* |Producer: LA | Producer: Remote |
* |Consumer: Remote | subsystem |
* | subsystem | Consumer: LA |
* | | |
* | Producer| Consumer|
* +-----------------------+------------------------+
* | |
* | |
* | +--------------------------------------+
* | |
* | |
* v v
* +--------------------------------------------------------------+
* | Header | Data | Control |
* +-----------+---+---+---+-----+----+--+--+-----+---+--+--+-----+
* | | b | b | b | | S |n |n | | S |n |n | |
* | Producer | l | l | l | | M |o |o | | M |o |o | |
* | Ver | o | o | o | | Q |d |d | | Q |d |d | |
* |-----------| c | c | c | ... | |e |e | ... | |e |e | ... |
* | | k | k | k | | O | | | | I | | | |
* | Consumer | | | | | u |0 |1 | | n |0 |1 | |
* | Ver | 0 | 1 | 2 | | t | | | | | | | |
* +-----------+---+---+---+-----+----+--+--+-----+---+--+--+-----+
* | |
* + |
* |
* +------------------------+
* |
* v
* +----+----+----+----+
* | SMQ Nodes |
* |----|----|----|----|
* Node # | 0 | 1 | 2 | ...|
* |----|----|----|----|
* Starting Block Index # | 0 | 3 | 8 | ...|
* |----|----|----|----|
* # of blocks | 3 | 5 | 1 | ...|
* +----+----+----+----+
*
* Header: Contains version numbers for software compatibility to ensure
* that both producers and consumers on the AP and subsystems know how to
* read from and write to the queue.
* Both the producer and consumer versions are 1.
* +---------+-------------------+
* | Size | Field |
* +---------+-------------------+
* | 1 byte | Producer Version |
* +---------+-------------------+
* | 1 byte | Consumer Version |
* +---------+-------------------+
*
* Data: The data portion contains multiple blocks [0..N] of a fixed size.
* The block size SM_BLOCKSIZE is fixed to 128 bytes for header version #1.
* Payload sent from the debug agent app is split (if necessary) and placed
* in these blocks. The first data block is placed at the next 8 byte aligned
* address after the header.
*
* The number of blocks for a given SMEM allocation is derived as follows:
* Number of Blocks = ((Total Size - Alignment - Size of Header
* - Size of SMQIn - Size of SMQOut)/(SM_BLOCKSIZE))
*
* The producer maintains a private block map of each of these blocks to
* determine which of these blocks in the queue is available and which are free.
*
* Control:
* The control portion contains a list of nodes [0..N] where N is number
* of available data blocks. Each node identifies the data
* block indexes that contain a particular debug message to be transferred,
* and the number of blocks it took to hold the contents of the message.
*
* Each node has the following structure:
* +---------+-------------------+
* | Size | Field |
* +---------+-------------------+
* | 2 bytes |Staring Block Index|
* +---------+-------------------+
* | 2 bytes |Number of Blocks |
* +---------+-------------------+
*
* The producer and the consumer update different parts of the control channel
* (SMQOut / SMQIn) respectively. Each of these control data structures contains
* information about the last node that was written / read, and the actual nodes
* that were written/read.
*
* SMQOut Structure (R/W by producer, R by consumer):
* +---------+-------------------+
* | Size | Field |
* +---------+-------------------+
* | 4 bytes | Magic Init Number |
* +---------+-------------------+
* | 4 bytes | Reset |
* +---------+-------------------+
* | 4 bytes | Last Sent Index |
* +---------+-------------------+
* | 4 bytes | Index Free Read |
* +---------+-------------------+
*
* SMQIn Structure (R/W by consumer, R by producer):
* +---------+-------------------+
* | Size | Field |
* +---------+-------------------+
* | 4 bytes | Magic Init Number |
* +---------+-------------------+
* | 4 bytes | Reset ACK |
* +---------+-------------------+
* | 4 bytes | Last Read Index |
* +---------+-------------------+
* | 4 bytes | Index Free Write |
* +---------+-------------------+
*
* Magic Init Number:
* Both SMQ Out and SMQ In initialize this field with a predefined magic
* number so as to make sure that both the consumer and producer blocks
* have fully initialized and have valid data in the shared memory control area.
* Producer Magic #: 0xFF00FF01
* Consumer Magic #: 0xFF00FF02
*/
static int smq_ctor(struct smq *smq, void *base_addr, int size,
enum smq_type type, struct mutex *lock_ptr)
{
int num_blocks;
uint8_t *pb_orig;
uint8_t *pb;
uint32_t i;
int err;
if (smq->initialized == SMQ_MAGIC_INIT) {
err = SMQ_EBADPARM;
goto bail;
}
if (!base_addr || !size) {
err = SMQ_EBADPARM;
goto bail;
}
if (type == PRODUCER)
smq->lock = lock_ptr;
pb_orig = (uint8_t *)base_addr;
smq->hdr = (struct smq_hdr *)pb_orig;
pb = pb_orig;
pb += sizeof(struct smq_hdr);
pb = PTR_ALIGN(pb, 8);
size -= pb - (uint8_t *)pb_orig;
num_blocks = (int)((size - sizeof(struct smq_out_state) -
sizeof(struct smq_in_state))/(SM_BLOCKSIZE +
sizeof(struct smq_node) * 2));
if (num_blocks <= 0) {
err = SMQ_ENOMEMORY;
goto bail;
}
smq->blocks = pb;
smq->num_blocks = num_blocks;
pb += num_blocks * SM_BLOCKSIZE;
smq->out = (struct smq_out *)pb;
pb += sizeof(struct smq_out_state) + (num_blocks *
sizeof(struct smq_node));
smq->in = (struct smq_in *)pb;
smq->type = type;
if (type == PRODUCER) {
smq->hdr->producer_version = SM_VERSION;
for (i = 0; i < smq->num_blocks; i++)
(smq->out->sent + i)->index_block = 0xFFFF;
err = smq_blockmap_ctor(&smq->block_map, smq->num_blocks);
if (err != SMQ_SUCCESS)
goto bail;
smq->out->s.index_sent_write = 0;
smq->out->s.index_free_read = 0;
if (smq->out->s.init == SMQ_MAGIC_PRODUCER) {
smq->out->s.index_check_queue_for_reset += 1;
} else {
smq->out->s.index_check_queue_for_reset = 1;
smq->out->s.init = SMQ_MAGIC_PRODUCER;
}
} else {
smq->hdr->consumer_version = SM_VERSION;
for (i = 0; i < smq->num_blocks; i++)
(smq->in->free + i)->index_block = 0xFFFF;
smq->in->s.index_sent_read = 0;
smq->in->s.index_free_write = 0;
if (smq->out->s.init == SMQ_MAGIC_PRODUCER) {
smq->in->s.index_check_queue_for_reset_ack =
smq->out->s.index_check_queue_for_reset;
} else {
smq->in->s.index_check_queue_for_reset_ack = 0;
}
smq->in->s.init = SMQ_MAGIC_CONSUMER;
}
smq->initialized = SMQ_MAGIC_INIT;
err = SMQ_SUCCESS;
bail:
return err;
}
static void send_interrupt_to_subsystem(struct rdbg_data *rdbgdata)
{
int offset = rdbgdata->gpio_out_offset;
int val = 1 ^ gpio_get_value(rdbgdata->out.gpio_base_id + offset);
gpio_set_value(rdbgdata->out.gpio_base_id + offset, val);
rdbgdata->gpio_out_offset = (offset + 1) % 32;
dev_dbg(rdbgdata->device, "%s: sent interrupt %d to subsystem",
__func__, val);
}
static irqreturn_t on_interrupt_from(int irq, void *ptr)
{
struct rdbg_data *rdbgdata = (struct rdbg_data *) ptr;
dev_dbg(rdbgdata->device, "%s: Received interrupt %d from subsystem",
__func__, irq);
complete(&(rdbgdata->work));
return IRQ_HANDLED;
}
static int initialize_smq(struct rdbg_data *rdbgdata)
{
int err = 0;
unsigned char *smem_consumer_buffer = rdbgdata->smem_addr;
smem_consumer_buffer += (rdbgdata->smem_size/2);
if (smq_ctor(&(rdbgdata->producer_smrb), (void *)(rdbgdata->smem_addr),
((rdbgdata->smem_size)/2), PRODUCER, &rdbgdata->write_mutex)) {
dev_err(rdbgdata->device, "%s: smq producer allocation failed",
__func__);
err = -ENOMEM;
goto bail;
}
if (smq_ctor(&(rdbgdata->consumer_smrb), (void *)smem_consumer_buffer,
((rdbgdata->smem_size)/2), CONSUMER, NULL)) {
dev_err(rdbgdata->device, "%s: smq conmsumer allocation failed",
__func__);
err = -ENOMEM;
}
bail:
return err;
}
static int rdbg_open(struct inode *inode, struct file *filp)
{
int device_id = -1;
struct rdbg_device *device = &g_rdbg_instance;
struct rdbg_data *rdbgdata = NULL;
int err = 0;
if (!inode || !device->rdbg_data) {
pr_err("Memory not allocated yet");
err = -ENODEV;
goto bail;
}
device_id = MINOR(inode->i_rdev);
rdbgdata = &device->rdbg_data[device_id];
if (rdbgdata->device_opened) {
dev_err(rdbgdata->device, "%s: Device already opened",
__func__);
err = -EEXIST;
goto bail;
}
rdbgdata->smem_size = proc_info[device_id].smem_buffer_size;
if (!rdbgdata->smem_size) {
dev_err(rdbgdata->device, "%s: smem not initialized", __func__);
err = -ENOMEM;
goto bail;
}
rdbgdata->smem_addr = smem_find(proc_info[device_id].smem_buffer_addr,
rdbgdata->smem_size, 0, SMEM_ANY_HOST_FLAG);
if (!rdbgdata->smem_addr) {
dev_err(rdbgdata->device, "%s: Could not allocate smem memory",
__func__);
err = -ENOMEM;
goto bail;
}
dev_dbg(rdbgdata->device, "%s: SMEM address=0x%lx smem_size=%d",
__func__, (unsigned long)rdbgdata->smem_addr,
(unsigned int)rdbgdata->smem_size);
if (check_subsystem_debug_enabled(rdbgdata->smem_addr,
rdbgdata->smem_size/2)) {
dev_err(rdbgdata->device, "%s: Subsystem %s is not debug enabled",
__func__, proc_info[device_id].name);
err = -ECOMM;
goto bail;
}
init_completion(&rdbgdata->work);
err = request_irq(rdbgdata->in.irq_base_id, on_interrupt_from,
IRQF_TRIGGER_RISING | IRQF_TRIGGER_FALLING,
proc_info[device_id].name,
(void *)&device->rdbg_data[device_id]);
if (err) {
dev_err(rdbgdata->device,
"%s: Failed to register interrupt.Err=%d,irqid=%d.",
__func__, err, rdbgdata->in.irq_base_id);
goto irq_bail;
}
err = enable_irq_wake(rdbgdata->in.irq_base_id);
if (err < 0) {
dev_dbg(rdbgdata->device, "enable_irq_wake() failed with err=%d",
err);
err = 0;
}
mutex_init(&rdbgdata->write_mutex);
err = initialize_smq(rdbgdata);
if (err) {
dev_err(rdbgdata->device, "Error initializing smq. Err=%d",
err);
goto smq_bail;
}
rdbgdata->device_opened = 1;
filp->private_data = (void *)rdbgdata;
return 0;
smq_bail:
smq_dtor(&(rdbgdata->producer_smrb));
smq_dtor(&(rdbgdata->consumer_smrb));
mutex_destroy(&rdbgdata->write_mutex);
irq_bail:
free_irq(rdbgdata->in.irq_base_id, (void *)
&device->rdbg_data[device_id]);
bail:
return err;
}
static int rdbg_release(struct inode *inode, struct file *filp)
{
int device_id = -1;
struct rdbg_device *rdbgdevice = &g_rdbg_instance;
struct rdbg_data *rdbgdata = NULL;
int err = 0;
if (!inode || !rdbgdevice->rdbg_data) {
pr_err("Memory not allocated yet");
err = -ENODEV;
goto bail;
}
device_id = MINOR(inode->i_rdev);
rdbgdata = &rdbgdevice->rdbg_data[device_id];
if (rdbgdata->device_opened == 1) {
dev_dbg(rdbgdata->device, "%s: Destroying %s.", __func__,
proc_info[device_id].name);
rdbgdata->device_opened = 0;
complete(&(rdbgdata->work));
free_irq(rdbgdata->in.irq_base_id, (void *)
&rdbgdevice->rdbg_data[device_id]);
if (rdbgdevice->rdbg_data[device_id].producer_smrb.initialized)
smq_dtor(&(rdbgdevice->rdbg_data[device_id].
producer_smrb));
if (rdbgdevice->rdbg_data[device_id].consumer_smrb.initialized)
smq_dtor(&(rdbgdevice->rdbg_data[device_id].
consumer_smrb));
mutex_destroy(&rdbgdata->write_mutex);
}
filp->private_data = NULL;
bail:
return err;
}
static ssize_t rdbg_read(struct file *filp, char __user *buf, size_t size,
loff_t *offset)
{
int err = 0;
struct rdbg_data *rdbgdata = filp->private_data;
void *p_sent_buffer = NULL;
int nsize = 0;
int more = 0;
if (!rdbgdata) {
pr_err("Invalid argument");
err = -EINVAL;
goto bail;
}
dev_dbg(rdbgdata->device, "%s: In receive", __func__);
err = wait_for_completion_interruptible(&(rdbgdata->work));
if (err) {
dev_err(rdbgdata->device, "%s: Error in wait", __func__);
goto bail;
}
smq_check_queue_reset(&(rdbgdata->consumer_smrb),
&(rdbgdata->producer_smrb));
if (smq_receive(&(rdbgdata->consumer_smrb), &p_sent_buffer,
&nsize, &more) != SMQ_SUCCESS) {
dev_err(rdbgdata->device, "%s: Error in smq_recv(). Err code = %d",
__func__, err);
err = -ENODATA;
goto bail;
}
size = ((size < nsize) ? size : nsize);
err = copy_to_user(buf, p_sent_buffer, size);
if (err != 0) {
dev_err(rdbgdata->device, "%s: Error in copy_to_user(). Err code = %d",
__func__, err);
err = -ENODATA;
goto bail;
}
smq_free(&(rdbgdata->consumer_smrb), p_sent_buffer);
err = size;
dev_dbg(rdbgdata->device, "%s: Read data to buffer with address 0x%lx",
__func__, (unsigned long) buf);
bail:
return err;
}
static ssize_t rdbg_write(struct file *filp, const char __user *buf,
size_t size, loff_t *offset)
{
int err = 0;
int num_retries = 0;
struct rdbg_data *rdbgdata = filp->private_data;
if (!rdbgdata) {
pr_err("Invalid argument");
err = -EINVAL;
goto bail;
}
do {
err = smq_alloc_send(&(rdbgdata->producer_smrb), buf, size);
dev_dbg(rdbgdata->device, "%s, smq_alloc_send returned %d.",
__func__, err);
} while (err != 0 && num_retries++ < MAX_RETRIES);
if (err != 0) {
err = -ECOMM;
goto bail;
}
send_interrupt_to_subsystem(rdbgdata);
err = size;
bail:
return err;
}
static const struct file_operations rdbg_fops = {
.open = rdbg_open,
.read = rdbg_read,
.write = rdbg_write,
.release = rdbg_release,
};
static int register_smp2p(char *node_name, struct gpio_info *gpio_info_ptr)
{
struct device_node *node = NULL;
int cnt = 0;
int id = 0;
node = of_find_compatible_node(NULL, NULL, node_name);
if (node) {
cnt = of_gpio_count(node);
if (cnt && gpio_info_ptr) {
id = of_get_gpio(node, 0);
gpio_info_ptr->gpio_base_id = id;
gpio_info_ptr->irq_base_id = gpio_to_irq(id);
return 0;
}
}
return -EINVAL;
}
static int __init rdbg_init(void)
{
int err = 0;
struct rdbg_device *rdbgdevice = &g_rdbg_instance;
int minor = 0;
int major = 0;
int minor_nodes_created = 0;
char *rdbg_compatible_string = "qcom,smp2pgpio_client_rdbg_";
int max_len = strlen(rdbg_compatible_string) + strlen("xx_out");
char *node_name = kcalloc(max_len, sizeof(char), GFP_KERNEL);
if (!node_name) {
err = -ENOMEM;
goto bail;
}
if (rdbgdevice->num_devices < 1 ||
rdbgdevice->num_devices > SMP2P_NUM_PROCS) {
pr_err("rgdb: invalid num_devices");
err = -EDOM;
goto name_bail;
}
rdbgdevice->rdbg_data = kcalloc(rdbgdevice->num_devices,
sizeof(struct rdbg_data), GFP_KERNEL);
if (!rdbgdevice->rdbg_data) {
err = -ENOMEM;
goto name_bail;
}
err = alloc_chrdev_region(&rdbgdevice->dev_no, 0,
rdbgdevice->num_devices, "rdbgctl");
if (err) {
pr_err("Error in alloc_chrdev_region.");
goto data_bail;
}
major = MAJOR(rdbgdevice->dev_no);
cdev_init(&rdbgdevice->cdev, &rdbg_fops);
rdbgdevice->cdev.owner = THIS_MODULE;
err = cdev_add(&rdbgdevice->cdev, MKDEV(major, 0),
rdbgdevice->num_devices);
if (err) {
pr_err("Error in cdev_add");
goto chrdev_bail;
}
rdbgdevice->class = class_create(THIS_MODULE, "rdbg");
if (IS_ERR(rdbgdevice->class)) {
err = PTR_ERR(rdbgdevice->class);
pr_err("Error in class_create");
goto cdev_bail;
}
for (minor = 0; minor < rdbgdevice->num_devices; minor++) {
if (!proc_info[minor].name)
continue;
if (snprintf(node_name, max_len, "%s%d_in",
rdbg_compatible_string, minor) <= 0) {
pr_err("Error in snprintf");
err = -ENOMEM;
goto device_bail;
}
if (register_smp2p(node_name,
&rdbgdevice->rdbg_data[minor].in)) {
pr_debug("No incoming device tree entry found for %s",
proc_info[minor].name);
continue;
}
if (snprintf(node_name, max_len, "%s%d_out",
rdbg_compatible_string, minor) <= 0) {
pr_err("Error in snprintf");
err = -ENOMEM;
goto device_bail;
}
if (register_smp2p(node_name,
&rdbgdevice->rdbg_data[minor].out)) {
pr_err("No outgoing device tree entry found for %s",
proc_info[minor].name);
err = -EINVAL;
goto device_bail;
}
rdbgdevice->rdbg_data[minor].device = device_create(
rdbgdevice->class, NULL, MKDEV(major, minor),
NULL, "%s", proc_info[minor].name);
if (IS_ERR(rdbgdevice->rdbg_data[minor].device)) {
err = PTR_ERR(rdbgdevice->rdbg_data[minor].device);
pr_err("Error in device_create");
goto device_bail;
}
rdbgdevice->rdbg_data[minor].device_initialized = 1;
minor_nodes_created++;
dev_dbg(rdbgdevice->rdbg_data[minor].device,
"%s: created /dev/%s c %d %d'", __func__,
proc_info[minor].name, major, minor);
}
if (!minor_nodes_created) {
pr_err("No device tree entries found");
err = -EINVAL;
goto class_bail;
}
goto name_bail;
device_bail:
for (--minor; minor >= 0; minor--) {
if (rdbgdevice->rdbg_data[minor].device_initialized)
device_destroy(rdbgdevice->class,
MKDEV(MAJOR(rdbgdevice->dev_no), minor));
}
class_bail:
class_destroy(rdbgdevice->class);
cdev_bail:
cdev_del(&rdbgdevice->cdev);
chrdev_bail:
unregister_chrdev_region(rdbgdevice->dev_no, rdbgdevice->num_devices);
data_bail:
kfree(rdbgdevice->rdbg_data);
name_bail:
kfree(node_name);
bail:
return err;
}
static void __exit rdbg_exit(void)
{
struct rdbg_device *rdbgdevice = &g_rdbg_instance;
int minor;
for (minor = 0; minor < rdbgdevice->num_devices; minor++) {
if (rdbgdevice->rdbg_data[minor].device_initialized) {
device_destroy(rdbgdevice->class,
MKDEV(MAJOR(rdbgdevice->dev_no), minor));
}
}
class_destroy(rdbgdevice->class);
cdev_del(&rdbgdevice->cdev);
unregister_chrdev_region(rdbgdevice->dev_no, 1);
kfree(rdbgdevice->rdbg_data);
}
module_init(rdbg_init);
module_exit(rdbg_exit);
MODULE_DESCRIPTION("rdbg module");
MODULE_LICENSE("GPL v2");