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linux-stable/drivers/net/wwan/iosm/iosm_ipc_mux_codec.c

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// SPDX-License-Identifier: GPL-2.0-only
/*
* Copyright (C) 2020-21 Intel Corporation.
*/
#include <linux/nospec.h>
#include "iosm_ipc_imem_ops.h"
#include "iosm_ipc_mux_codec.h"
#include "iosm_ipc_task_queue.h"
/* Test the link power state and send a MUX command in blocking mode. */
static int ipc_mux_tq_cmd_send(struct iosm_imem *ipc_imem, int arg, void *msg,
size_t size)
{
struct iosm_mux *ipc_mux = ipc_imem->mux;
const struct mux_acb *acb = msg;
skb_queue_tail(&ipc_mux->channel->ul_list, acb->skb);
ipc_imem_ul_send(ipc_mux->imem);
return 0;
}
static int ipc_mux_acb_send(struct iosm_mux *ipc_mux, bool blocking)
{
struct completion *completion = &ipc_mux->channel->ul_sem;
int ret = ipc_task_queue_send_task(ipc_mux->imem, ipc_mux_tq_cmd_send,
0, &ipc_mux->acb,
sizeof(ipc_mux->acb), false);
if (ret) {
dev_err(ipc_mux->dev, "unable to send mux command");
return ret;
}
/* if blocking, suspend the app and wait for irq in the flash or
* crash phase. return false on timeout to indicate failure.
*/
if (blocking) {
u32 wait_time_milliseconds = IPC_MUX_CMD_RUN_DEFAULT_TIMEOUT;
reinit_completion(completion);
if (wait_for_completion_interruptible_timeout
(completion, msecs_to_jiffies(wait_time_milliseconds)) ==
0) {
dev_err(ipc_mux->dev, "ch[%d] timeout",
ipc_mux->channel_id);
ipc_uevent_send(ipc_mux->imem->dev, UEVENT_MDM_TIMEOUT);
return -ETIMEDOUT;
}
}
return 0;
}
/* Initialize the command header. */
static void ipc_mux_acb_init(struct iosm_mux *ipc_mux)
{
struct mux_acb *acb = &ipc_mux->acb;
struct mux_acbh *header;
header = (struct mux_acbh *)(acb->skb)->data;
header->block_length = cpu_to_le32(sizeof(struct mux_acbh));
header->first_cmd_index = header->block_length;
header->signature = cpu_to_le32(IOSM_AGGR_MUX_SIG_ACBH);
header->sequence_nr = cpu_to_le16(ipc_mux->acb_tx_sequence_nr++);
}
/* Add a command to the ACB. */
static struct mux_cmdh *ipc_mux_acb_add_cmd(struct iosm_mux *ipc_mux, u32 cmd,
void *param, u32 param_size)
{
struct mux_acbh *header;
struct mux_cmdh *cmdh;
struct mux_acb *acb;
acb = &ipc_mux->acb;
header = (struct mux_acbh *)(acb->skb)->data;
cmdh = (struct mux_cmdh *)
((acb->skb)->data + le32_to_cpu(header->block_length));
cmdh->signature = cpu_to_le32(MUX_SIG_CMDH);
cmdh->command_type = cpu_to_le32(cmd);
cmdh->if_id = acb->if_id;
acb->cmd = cmd;
cmdh->cmd_len = cpu_to_le16(offsetof(struct mux_cmdh, param) +
param_size);
cmdh->transaction_id = cpu_to_le32(ipc_mux->tx_transaction_id++);
if (param)
memcpy(&cmdh->param, param, param_size);
skb_put(acb->skb, le32_to_cpu(header->block_length) +
le16_to_cpu(cmdh->cmd_len));
return cmdh;
}
/* Prepare mux Command */
static struct mux_lite_cmdh *ipc_mux_lite_add_cmd(struct iosm_mux *ipc_mux,
u32 cmd, struct mux_acb *acb,
void *param, u32 param_size)
{
struct mux_lite_cmdh *cmdh = (struct mux_lite_cmdh *)acb->skb->data;
cmdh->signature = cpu_to_le32(MUX_SIG_CMDH);
cmdh->command_type = cpu_to_le32(cmd);
cmdh->if_id = acb->if_id;
acb->cmd = cmd;
cmdh->cmd_len = cpu_to_le16(offsetof(struct mux_lite_cmdh, param) +
param_size);
cmdh->transaction_id = cpu_to_le32(ipc_mux->tx_transaction_id++);
if (param)
memcpy(&cmdh->param, param, param_size);
skb_put(acb->skb, le16_to_cpu(cmdh->cmd_len));
return cmdh;
}
static int ipc_mux_acb_alloc(struct iosm_mux *ipc_mux)
{
struct mux_acb *acb = &ipc_mux->acb;
struct sk_buff *skb;
dma_addr_t mapping;
/* Allocate skb memory for the uplink buffer. */
skb = ipc_pcie_alloc_skb(ipc_mux->pcie, MUX_MAX_UL_ACB_BUF_SIZE,
GFP_ATOMIC, &mapping, DMA_TO_DEVICE, 0);
if (!skb)
return -ENOMEM;
/* Save the skb address. */
acb->skb = skb;
memset(skb->data, 0, MUX_MAX_UL_ACB_BUF_SIZE);
return 0;
}
int ipc_mux_dl_acb_send_cmds(struct iosm_mux *ipc_mux, u32 cmd_type, u8 if_id,
u32 transaction_id, union mux_cmd_param *param,
size_t res_size, bool blocking, bool respond)
{
struct mux_acb *acb = &ipc_mux->acb;
union mux_type_cmdh cmdh;
int ret = 0;
acb->if_id = if_id;
ret = ipc_mux_acb_alloc(ipc_mux);
if (ret)
return ret;
if (ipc_mux->protocol == MUX_LITE) {
cmdh.ack_lite = ipc_mux_lite_add_cmd(ipc_mux, cmd_type, acb,
param, res_size);
if (respond)
cmdh.ack_lite->transaction_id =
cpu_to_le32(transaction_id);
} else {
/* Initialize the ACB header. */
ipc_mux_acb_init(ipc_mux);
cmdh.ack_aggr = ipc_mux_acb_add_cmd(ipc_mux, cmd_type, param,
res_size);
if (respond)
cmdh.ack_aggr->transaction_id =
cpu_to_le32(transaction_id);
}
ret = ipc_mux_acb_send(ipc_mux, blocking);
return ret;
}
void ipc_mux_netif_tx_flowctrl(struct mux_session *session, int idx, bool on)
{
/* Inform the network interface to start/stop flow ctrl */
ipc_wwan_tx_flowctrl(session->wwan, idx, on);
}
static int ipc_mux_dl_cmdresps_decode_process(struct iosm_mux *ipc_mux,
union mux_cmd_param param,
__le32 command_type, u8 if_id,
__le32 transaction_id)
{
struct mux_acb *acb = &ipc_mux->acb;
switch (le32_to_cpu(command_type)) {
case MUX_CMD_OPEN_SESSION_RESP:
case MUX_CMD_CLOSE_SESSION_RESP:
/* Resume the control application. */
acb->got_param = param;
break;
case MUX_LITE_CMD_FLOW_CTL_ACK:
/* This command type is not expected as response for
* Aggregation version of the protocol. So return non-zero.
*/
if (ipc_mux->protocol != MUX_LITE)
return -EINVAL;
dev_dbg(ipc_mux->dev, "if_id %u FLOW_CTL_ACK %u received",
if_id, le32_to_cpu(transaction_id));
break;
case IOSM_AGGR_MUX_CMD_FLOW_CTL_ACK:
/* This command type is not expected as response for
* Lite version of the protocol. So return non-zero.
*/
if (ipc_mux->protocol == MUX_LITE)
return -EINVAL;
break;
default:
return -EINVAL;
}
acb->wanted_response = MUX_CMD_INVALID;
acb->got_response = le32_to_cpu(command_type);
complete(&ipc_mux->channel->ul_sem);
return 0;
}
static int ipc_mux_dl_cmds_decode_process(struct iosm_mux *ipc_mux,
union mux_cmd_param *param,
__le32 command_type, u8 if_id,
__le16 cmd_len, int size)
{
struct mux_session *session;
struct hrtimer *adb_timer;
dev_dbg(ipc_mux->dev, "if_id[%d]: dlcmds decode process %d",
if_id, le32_to_cpu(command_type));
switch (le32_to_cpu(command_type)) {
case MUX_LITE_CMD_FLOW_CTL:
case IOSM_AGGR_MUX_CMD_FLOW_CTL_DISABLE:
if (if_id >= IPC_MEM_MUX_IP_SESSION_ENTRIES) {
dev_err(ipc_mux->dev, "if_id [%d] not valid",
if_id);
return -EINVAL; /* No session interface id. */
}
session = &ipc_mux->session[if_id];
adb_timer = &ipc_mux->imem->adb_timer;
if (param->flow_ctl.mask == cpu_to_le32(0xFFFFFFFF)) {
/* Backward Compatibility */
if (cmd_len == cpu_to_le16(size))
session->flow_ctl_mask =
le32_to_cpu(param->flow_ctl.mask);
else
session->flow_ctl_mask = ~0;
/* if CP asks for FLOW CTRL Enable
* then set our internal flow control Tx flag
* to limit uplink session queueing
*/
session->net_tx_stop = true;
/* We have to call Finish ADB here.
* Otherwise any already queued data
* will be sent to CP when ADB is full
* for some other sessions.
*/
if (ipc_mux->protocol == MUX_AGGREGATION) {
ipc_mux_ul_adb_finish(ipc_mux);
ipc_imem_hrtimer_stop(adb_timer);
}
/* Update the stats */
session->flow_ctl_en_cnt++;
} else if (param->flow_ctl.mask == 0) {
/* Just reset the Flow control mask and let
* mux_flow_ctrl_low_thre_b take control on
* our internal Tx flag and enabling kernel
* flow control
*/
dev_dbg(ipc_mux->dev, "if_id[%u] flow_ctl mask 0x%08X",
if_id, le32_to_cpu(param->flow_ctl.mask));
/* Backward Compatibility */
if (cmd_len == cpu_to_le16(size))
session->flow_ctl_mask =
le32_to_cpu(param->flow_ctl.mask);
else
session->flow_ctl_mask = 0;
/* Update the stats */
session->flow_ctl_dis_cnt++;
} else {
break;
}
ipc_mux->acc_adb_size = 0;
ipc_mux->acc_payload_size = 0;
dev_dbg(ipc_mux->dev, "if_id[%u] FLOW CTRL 0x%08X", if_id,
le32_to_cpu(param->flow_ctl.mask));
break;
case MUX_LITE_CMD_LINK_STATUS_REPORT:
break;
default:
return -EINVAL;
}
return 0;
}
/* Decode and Send appropriate response to a command block. */
static void ipc_mux_dl_cmd_decode(struct iosm_mux *ipc_mux, struct sk_buff *skb)
{
struct mux_lite_cmdh *cmdh = (struct mux_lite_cmdh *)skb->data;
__le32 trans_id = cmdh->transaction_id;
int size;
if (ipc_mux_dl_cmdresps_decode_process(ipc_mux, cmdh->param,
cmdh->command_type, cmdh->if_id,
cmdh->transaction_id)) {
/* Unable to decode command response indicates the cmd_type
* may be a command instead of response. So try to decoding it.
*/
size = offsetof(struct mux_lite_cmdh, param) +
sizeof(cmdh->param.flow_ctl);
if (!ipc_mux_dl_cmds_decode_process(ipc_mux, &cmdh->param,
cmdh->command_type,
cmdh->if_id,
cmdh->cmd_len, size)) {
/* Decoded command may need a response. Give the
* response according to the command type.
*/
union mux_cmd_param *mux_cmd = NULL;
size_t size = 0;
u32 cmd = MUX_LITE_CMD_LINK_STATUS_REPORT_RESP;
if (cmdh->command_type ==
cpu_to_le32(MUX_LITE_CMD_LINK_STATUS_REPORT)) {
mux_cmd = &cmdh->param;
mux_cmd->link_status_resp.response =
cpu_to_le32(MUX_CMD_RESP_SUCCESS);
/* response field is u32 */
size = sizeof(u32);
} else if (cmdh->command_type ==
cpu_to_le32(MUX_LITE_CMD_FLOW_CTL)) {
cmd = MUX_LITE_CMD_FLOW_CTL_ACK;
} else {
return;
}
if (ipc_mux_dl_acb_send_cmds(ipc_mux, cmd, cmdh->if_id,
le32_to_cpu(trans_id),
mux_cmd, size, false,
true))
dev_err(ipc_mux->dev,
"if_id %d: cmd send failed",
cmdh->if_id);
}
}
}
/* Pass the DL packet to the netif layer. */
static int ipc_mux_net_receive(struct iosm_mux *ipc_mux, int if_id,
struct iosm_wwan *wwan, u32 offset,
u8 service_class, struct sk_buff *skb,
u32 pkt_len)
{
struct sk_buff *dest_skb = skb_clone(skb, GFP_ATOMIC);
if (!dest_skb)
return -ENOMEM;
skb_pull(dest_skb, offset);
skb_trim(dest_skb, pkt_len);
/* Pass the packet to the netif layer. */
dest_skb->priority = service_class;
return ipc_wwan_receive(wwan, dest_skb, false, if_id);
}
/* Decode Flow Credit Table in the block */
static void ipc_mux_dl_fcth_decode(struct iosm_mux *ipc_mux,
unsigned char *block)
{
struct ipc_mem_lite_gen_tbl *fct = (struct ipc_mem_lite_gen_tbl *)block;
struct iosm_wwan *wwan;
int ul_credits;
int if_id;
if (fct->vfl_length != sizeof(fct->vfl.nr_of_bytes)) {
dev_err(ipc_mux->dev, "unexpected FCT length: %d",
fct->vfl_length);
return;
}
if_id = fct->if_id;
if (if_id >= IPC_MEM_MUX_IP_SESSION_ENTRIES) {
dev_err(ipc_mux->dev, "not supported if_id: %d", if_id);
return;
}
/* Is the session active ? */
if_id = array_index_nospec(if_id, IPC_MEM_MUX_IP_SESSION_ENTRIES);
wwan = ipc_mux->session[if_id].wwan;
if (!wwan) {
dev_err(ipc_mux->dev, "session Net ID is NULL");
return;
}
ul_credits = le32_to_cpu(fct->vfl.nr_of_bytes);
dev_dbg(ipc_mux->dev, "Flow_Credit:: if_id[%d] Old: %d Grants: %d",
if_id, ipc_mux->session[if_id].ul_flow_credits, ul_credits);
/* Update the Flow Credit information from ADB */
ipc_mux->session[if_id].ul_flow_credits += ul_credits;
/* Check whether the TX can be started */
if (ipc_mux->session[if_id].ul_flow_credits > 0) {
ipc_mux->session[if_id].net_tx_stop = false;
ipc_mux_netif_tx_flowctrl(&ipc_mux->session[if_id],
ipc_mux->session[if_id].if_id, false);
}
}
/* Decode non-aggregated datagram */
static void ipc_mux_dl_adgh_decode(struct iosm_mux *ipc_mux,
struct sk_buff *skb)
{
u32 pad_len, packet_offset, adgh_len;
struct iosm_wwan *wwan;
struct mux_adgh *adgh;
u8 *block = skb->data;
int rc = 0;
u8 if_id;
adgh = (struct mux_adgh *)block;
if (adgh->signature != cpu_to_le32(IOSM_AGGR_MUX_SIG_ADGH)) {
dev_err(ipc_mux->dev, "invalid ADGH signature received");
return;
}
if_id = adgh->if_id;
if (if_id >= IPC_MEM_MUX_IP_SESSION_ENTRIES) {
dev_err(ipc_mux->dev, "invalid if_id while decoding %d", if_id);
return;
}
/* Is the session active ? */
if_id = array_index_nospec(if_id, IPC_MEM_MUX_IP_SESSION_ENTRIES);
wwan = ipc_mux->session[if_id].wwan;
if (!wwan) {
dev_err(ipc_mux->dev, "session Net ID is NULL");
return;
}
/* Store the pad len for the corresponding session
* Pad bytes as negotiated in the open session less the header size
* (see session management chapter for details).
* If resulting padding is zero or less, the additional head padding is
* omitted. For e.g., if HEAD_PAD_LEN = 16 or less, this field is
* omitted if HEAD_PAD_LEN = 20, then this field will have 4 bytes
* set to zero
*/
pad_len =
ipc_mux->session[if_id].dl_head_pad_len - IPC_MEM_DL_ETH_OFFSET;
packet_offset = sizeof(*adgh) + pad_len;
if_id += ipc_mux->wwan_q_offset;
adgh_len = le16_to_cpu(adgh->length);
/* Pass the packet to the netif layer */
rc = ipc_mux_net_receive(ipc_mux, if_id, wwan, packet_offset,
adgh->service_class, skb,
adgh_len - packet_offset);
if (rc) {
dev_err(ipc_mux->dev, "mux adgh decoding error");
return;
}
ipc_mux->session[if_id].flush = 1;
}
static void ipc_mux_dl_acbcmd_decode(struct iosm_mux *ipc_mux,
struct mux_cmdh *cmdh, int size)
{
u32 link_st = IOSM_AGGR_MUX_CMD_LINK_STATUS_REPORT_RESP;
u32 fctl_dis = IOSM_AGGR_MUX_CMD_FLOW_CTL_DISABLE;
u32 fctl_ena = IOSM_AGGR_MUX_CMD_FLOW_CTL_ENABLE;
u32 fctl_ack = IOSM_AGGR_MUX_CMD_FLOW_CTL_ACK;
union mux_cmd_param *cmd_p = NULL;
u32 cmd = link_st;
u32 trans_id;
if (!ipc_mux_dl_cmds_decode_process(ipc_mux, &cmdh->param,
cmdh->command_type, cmdh->if_id,
cmdh->cmd_len, size)) {
size = 0;
if (cmdh->command_type == cpu_to_le32(link_st)) {
cmd_p = &cmdh->param;
cmd_p->link_status_resp.response = MUX_CMD_RESP_SUCCESS;
} else if ((cmdh->command_type == cpu_to_le32(fctl_ena)) ||
(cmdh->command_type == cpu_to_le32(fctl_dis))) {
cmd = fctl_ack;
} else {
return;
}
trans_id = le32_to_cpu(cmdh->transaction_id);
ipc_mux_dl_acb_send_cmds(ipc_mux, cmd, cmdh->if_id,
trans_id, cmd_p, size, false, true);
}
}
/* Decode an aggregated command block. */
static void ipc_mux_dl_acb_decode(struct iosm_mux *ipc_mux, struct sk_buff *skb)
{
struct mux_acbh *acbh;
struct mux_cmdh *cmdh;
u32 next_cmd_index;
u8 *block;
int size;
acbh = (struct mux_acbh *)(skb->data);
block = (u8 *)(skb->data);
next_cmd_index = le32_to_cpu(acbh->first_cmd_index);
next_cmd_index = array_index_nospec(next_cmd_index,
sizeof(struct mux_cmdh));
while (next_cmd_index != 0) {
cmdh = (struct mux_cmdh *)&block[next_cmd_index];
next_cmd_index = le32_to_cpu(cmdh->next_cmd_index);
if (ipc_mux_dl_cmdresps_decode_process(ipc_mux, cmdh->param,
cmdh->command_type,
cmdh->if_id,
cmdh->transaction_id)) {
size = offsetof(struct mux_cmdh, param) +
sizeof(cmdh->param.flow_ctl);
ipc_mux_dl_acbcmd_decode(ipc_mux, cmdh, size);
}
}
}
/* process datagram */
static int mux_dl_process_dg(struct iosm_mux *ipc_mux, struct mux_adbh *adbh,
struct mux_adth_dg *dg, struct sk_buff *skb,
int if_id, int nr_of_dg)
{
u32 dl_head_pad_len = ipc_mux->session[if_id].dl_head_pad_len;
u32 packet_offset, i, rc, dg_len;
for (i = 0; i < nr_of_dg; i++, dg++) {
if (le32_to_cpu(dg->datagram_index)
< sizeof(struct mux_adbh))
goto dg_error;
/* Is the packet inside of the ADB */
if (le32_to_cpu(dg->datagram_index) >=
le32_to_cpu(adbh->block_length)) {
goto dg_error;
} else {
packet_offset =
le32_to_cpu(dg->datagram_index) +
dl_head_pad_len;
dg_len = le16_to_cpu(dg->datagram_length);
/* Pass the packet to the netif layer. */
rc = ipc_mux_net_receive(ipc_mux, if_id, ipc_mux->wwan,
packet_offset,
dg->service_class, skb,
dg_len - dl_head_pad_len);
if (rc)
goto dg_error;
}
}
return 0;
dg_error:
return -1;
}
/* Decode an aggregated data block. */
static void mux_dl_adb_decode(struct iosm_mux *ipc_mux,
struct sk_buff *skb)
{
struct mux_adth_dg *dg;
struct iosm_wwan *wwan;
struct mux_adbh *adbh;
struct mux_adth *adth;
int nr_of_dg, if_id;
u32 adth_index;
u8 *block;
block = skb->data;
adbh = (struct mux_adbh *)block;
/* Process the aggregated datagram tables. */
adth_index = le32_to_cpu(adbh->first_table_index);
/* Has CP sent an empty ADB ? */
if (adth_index < 1) {
dev_err(ipc_mux->dev, "unexpected empty ADB");
goto adb_decode_err;
}
/* Loop through mixed session tables. */
while (adth_index) {
/* Get the reference to the table header. */
adth = (struct mux_adth *)(block + adth_index);
/* Get the interface id and map it to the netif id. */
if_id = adth->if_id;
if (if_id >= IPC_MEM_MUX_IP_SESSION_ENTRIES)
goto adb_decode_err;
if_id = array_index_nospec(if_id,
IPC_MEM_MUX_IP_SESSION_ENTRIES);
/* Is the session active ? */
wwan = ipc_mux->session[if_id].wwan;
if (!wwan)
goto adb_decode_err;
/* Consistency checks for aggregated datagram table. */
if (adth->signature != cpu_to_le32(IOSM_AGGR_MUX_SIG_ADTH))
goto adb_decode_err;
if (le16_to_cpu(adth->table_length) < sizeof(struct mux_adth))
goto adb_decode_err;
/* Calculate the number of datagrams. */
nr_of_dg = (le16_to_cpu(adth->table_length) -
sizeof(struct mux_adth)) /
sizeof(struct mux_adth_dg);
/* Is the datagram table empty ? */
if (nr_of_dg < 1) {
dev_err(ipc_mux->dev,
"adthidx=%u,nr_of_dg=%d,next_tblidx=%u",
adth_index, nr_of_dg,
le32_to_cpu(adth->next_table_index));
/* Move to the next aggregated datagram table. */
adth_index = le32_to_cpu(adth->next_table_index);
continue;
}
/* New aggregated datagram table. */
dg = adth->dg;
if (mux_dl_process_dg(ipc_mux, adbh, dg, skb, if_id,
nr_of_dg) < 0)
goto adb_decode_err;
/* mark session for final flush */
ipc_mux->session[if_id].flush = 1;
/* Move to the next aggregated datagram table. */
adth_index = le32_to_cpu(adth->next_table_index);
}
adb_decode_err:
return;
}
/**
* ipc_mux_dl_decode - Route the DL packet through the IP MUX layer
* depending on Header.
* @ipc_mux: Pointer to MUX data-struct
* @skb: Pointer to ipc_skb.
*/
void ipc_mux_dl_decode(struct iosm_mux *ipc_mux, struct sk_buff *skb)
{
u32 signature;
if (!skb->data)
return;
/* Decode the MUX header type. */
signature = le32_to_cpup((__le32 *)skb->data);
switch (signature) {
case IOSM_AGGR_MUX_SIG_ADBH: /* Aggregated Data Block Header */
mux_dl_adb_decode(ipc_mux, skb);
break;
case IOSM_AGGR_MUX_SIG_ADGH:
ipc_mux_dl_adgh_decode(ipc_mux, skb);
break;
case MUX_SIG_FCTH:
ipc_mux_dl_fcth_decode(ipc_mux, skb->data);
break;
case IOSM_AGGR_MUX_SIG_ACBH: /* Aggregated Command Block Header */
ipc_mux_dl_acb_decode(ipc_mux, skb);
break;
case MUX_SIG_CMDH:
ipc_mux_dl_cmd_decode(ipc_mux, skb);
break;
default:
dev_err(ipc_mux->dev, "invalid ABH signature");
}
ipc_pcie_kfree_skb(ipc_mux->pcie, skb);
}
static int ipc_mux_ul_skb_alloc(struct iosm_mux *ipc_mux,
struct mux_adb *ul_adb, u32 type)
{
/* Take the first element of the free list. */
struct sk_buff *skb = skb_dequeue(&ul_adb->free_list);
u32 no_if = IPC_MEM_MUX_IP_SESSION_ENTRIES;
u32 *next_tb_id;
int qlt_size;
u32 if_id;
if (!skb)
return -EBUSY; /* Wait for a free ADB skb. */
/* Mark it as UL ADB to select the right free operation. */
IPC_CB(skb)->op_type = (u8)UL_MUX_OP_ADB;
switch (type) {
case IOSM_AGGR_MUX_SIG_ADBH:
/* Save the ADB memory settings. */
ul_adb->dest_skb = skb;
ul_adb->buf = skb->data;
ul_adb->size = IPC_MEM_MAX_ADB_BUF_SIZE;
/* reset statistic counter */
ul_adb->if_cnt = 0;
ul_adb->payload_size = 0;
ul_adb->dg_cnt_total = 0;
/* Initialize the ADBH. */
ul_adb->adbh = (struct mux_adbh *)ul_adb->buf;
memset(ul_adb->adbh, 0, sizeof(struct mux_adbh));
ul_adb->adbh->signature = cpu_to_le32(IOSM_AGGR_MUX_SIG_ADBH);
ul_adb->adbh->block_length =
cpu_to_le32(sizeof(struct mux_adbh));
next_tb_id = (unsigned int *)&ul_adb->adbh->first_table_index;
ul_adb->next_table_index = next_tb_id;
/* Clear the local copy of DGs for new ADB */
memset(ul_adb->dg, 0, sizeof(ul_adb->dg));
/* Clear the DG count and QLT updated status for new ADB */
for (if_id = 0; if_id < no_if; if_id++) {
ul_adb->dg_count[if_id] = 0;
ul_adb->qlt_updated[if_id] = 0;
}
break;
case IOSM_AGGR_MUX_SIG_ADGH:
/* Save the ADB memory settings. */
ul_adb->dest_skb = skb;
ul_adb->buf = skb->data;
ul_adb->size = IPC_MEM_MAX_DL_MUX_LITE_BUF_SIZE;
/* reset statistic counter */
ul_adb->if_cnt = 0;
ul_adb->payload_size = 0;
ul_adb->dg_cnt_total = 0;
ul_adb->adgh = (struct mux_adgh *)skb->data;
memset(ul_adb->adgh, 0, sizeof(struct mux_adgh));
break;
case MUX_SIG_QLTH:
qlt_size = offsetof(struct ipc_mem_lite_gen_tbl, vfl) +
(MUX_QUEUE_LEVEL * sizeof(struct mux_lite_vfl));
if (qlt_size > IPC_MEM_MAX_DL_MUX_LITE_BUF_SIZE) {
dev_err(ipc_mux->dev,
"can't support. QLT size:%d SKB size: %d",
qlt_size, IPC_MEM_MAX_DL_MUX_LITE_BUF_SIZE);
return -ERANGE;
}
ul_adb->qlth_skb = skb;
memset((ul_adb->qlth_skb)->data, 0, qlt_size);
skb_put(skb, qlt_size);
break;
}
return 0;
}
static void ipc_mux_ul_adgh_finish(struct iosm_mux *ipc_mux)
{
struct mux_adb *ul_adb = &ipc_mux->ul_adb;
u16 adgh_len;
long long bytes;
char *str;
if (!ul_adb->dest_skb) {
dev_err(ipc_mux->dev, "no dest skb");
return;
}
adgh_len = le16_to_cpu(ul_adb->adgh->length);
skb_put(ul_adb->dest_skb, adgh_len);
skb_queue_tail(&ipc_mux->channel->ul_list, ul_adb->dest_skb);
ul_adb->dest_skb = NULL;
if (ipc_mux->ul_flow == MUX_UL_ON_CREDITS) {
struct mux_session *session;
session = &ipc_mux->session[ul_adb->adgh->if_id];
str = "available_credits";
bytes = (long long)session->ul_flow_credits;
} else {
str = "pend_bytes";
bytes = ipc_mux->ul_data_pend_bytes;
ipc_mux->ul_data_pend_bytes = ipc_mux->ul_data_pend_bytes +
adgh_len;
}
dev_dbg(ipc_mux->dev, "UL ADGH: size=%u, if_id=%d, payload=%d, %s=%lld",
adgh_len, ul_adb->adgh->if_id, ul_adb->payload_size,
str, bytes);
}
static void ipc_mux_ul_encode_adth(struct iosm_mux *ipc_mux,
struct mux_adb *ul_adb, int *out_offset)
{
int i, qlt_size, offset = *out_offset;
struct mux_qlth *p_adb_qlt;
struct mux_adth_dg *dg;
struct mux_adth *adth;
u16 adth_dg_size;
u32 *next_tb_id;
qlt_size = offsetof(struct mux_qlth, ql) +
MUX_QUEUE_LEVEL * sizeof(struct mux_qlth_ql);
for (i = 0; i < ipc_mux->nr_sessions; i++) {
if (ul_adb->dg_count[i] > 0) {
adth_dg_size = offsetof(struct mux_adth, dg) +
ul_adb->dg_count[i] * sizeof(*dg);
*ul_adb->next_table_index = offset;
adth = (struct mux_adth *)&ul_adb->buf[offset];
next_tb_id = (unsigned int *)&adth->next_table_index;
ul_adb->next_table_index = next_tb_id;
offset += adth_dg_size;
adth->signature = cpu_to_le32(IOSM_AGGR_MUX_SIG_ADTH);
adth->if_id = i;
adth->table_length = cpu_to_le16(adth_dg_size);
adth_dg_size -= offsetof(struct mux_adth, dg);
memcpy(adth->dg, ul_adb->dg[i], adth_dg_size);
ul_adb->if_cnt++;
}
if (ul_adb->qlt_updated[i]) {
*ul_adb->next_table_index = offset;
p_adb_qlt = (struct mux_qlth *)&ul_adb->buf[offset];
ul_adb->next_table_index =
(u32 *)&p_adb_qlt->next_table_index;
memcpy(p_adb_qlt, ul_adb->pp_qlt[i], qlt_size);
offset += qlt_size;
}
}
*out_offset = offset;
}
/**
* ipc_mux_ul_adb_finish - Add the TD of the aggregated session packets to TDR.
* @ipc_mux: Pointer to MUX data-struct.
*/
void ipc_mux_ul_adb_finish(struct iosm_mux *ipc_mux)
{
bool ul_data_pend = false;
struct mux_adb *ul_adb;
unsigned long flags;
int offset;
ul_adb = &ipc_mux->ul_adb;
if (!ul_adb->dest_skb)
return;
offset = *ul_adb->next_table_index;
ipc_mux_ul_encode_adth(ipc_mux, ul_adb, &offset);
ul_adb->adbh->block_length = cpu_to_le32(offset);
if (le32_to_cpu(ul_adb->adbh->block_length) > ul_adb->size) {
ul_adb->dest_skb = NULL;
return;
}
*ul_adb->next_table_index = 0;
ul_adb->adbh->sequence_nr = cpu_to_le16(ipc_mux->adb_tx_sequence_nr++);
skb_put(ul_adb->dest_skb, le32_to_cpu(ul_adb->adbh->block_length));
spin_lock_irqsave(&(&ipc_mux->channel->ul_list)->lock, flags);
__skb_queue_tail(&ipc_mux->channel->ul_list, ul_adb->dest_skb);
spin_unlock_irqrestore(&(&ipc_mux->channel->ul_list)->lock, flags);
ul_adb->dest_skb = NULL;
/* Updates the TDs with ul_list */
ul_data_pend = ipc_imem_ul_write_td(ipc_mux->imem);
/* Delay the doorbell irq */
if (ul_data_pend)
ipc_imem_td_update_timer_start(ipc_mux->imem);
ipc_mux->acc_adb_size += le32_to_cpu(ul_adb->adbh->block_length);
ipc_mux->acc_payload_size += ul_adb->payload_size;
ipc_mux->ul_data_pend_bytes += ul_adb->payload_size;
}
/* Allocates an ADB from the free list and initializes it with ADBH */
static bool ipc_mux_ul_adb_allocate(struct iosm_mux *ipc_mux,
struct mux_adb *adb, int *size_needed,
u32 type)
{
bool ret_val = false;
int status;
if (!adb->dest_skb) {
/* Allocate memory for the ADB including of the
* datagram table header.
*/
status = ipc_mux_ul_skb_alloc(ipc_mux, adb, type);
if (status)
/* Is a pending ADB available ? */
ret_val = true; /* None. */
/* Update size need to zero only for new ADB memory */
*size_needed = 0;
}
return ret_val;
}
/* Informs the network stack to stop sending further packets for all opened
* sessions
*/
static void ipc_mux_stop_tx_for_all_sessions(struct iosm_mux *ipc_mux)
{
struct mux_session *session;
int idx;
for (idx = 0; idx < IPC_MEM_MUX_IP_SESSION_ENTRIES; idx++) {
session = &ipc_mux->session[idx];
if (!session->wwan)
continue;
session->net_tx_stop = true;
}
}
/* Sends Queue Level Table of all opened sessions */
static bool ipc_mux_lite_send_qlt(struct iosm_mux *ipc_mux)
{
struct ipc_mem_lite_gen_tbl *qlt;
struct mux_session *session;
bool qlt_updated = false;
int i;
int qlt_size;
if (!ipc_mux->initialized || ipc_mux->state != MUX_S_ACTIVE)
return qlt_updated;
qlt_size = offsetof(struct ipc_mem_lite_gen_tbl, vfl) +
MUX_QUEUE_LEVEL * sizeof(struct mux_lite_vfl);
for (i = 0; i < IPC_MEM_MUX_IP_SESSION_ENTRIES; i++) {
session = &ipc_mux->session[i];
if (!session->wwan || session->flow_ctl_mask)
continue;
if (ipc_mux_ul_skb_alloc(ipc_mux, &ipc_mux->ul_adb,
MUX_SIG_QLTH)) {
dev_err(ipc_mux->dev,
"no reserved mem to send QLT of if_id: %d", i);
break;
}
/* Prepare QLT */
qlt = (struct ipc_mem_lite_gen_tbl *)(ipc_mux->ul_adb.qlth_skb)
->data;
qlt->signature = cpu_to_le32(MUX_SIG_QLTH);
qlt->length = cpu_to_le16(qlt_size);
qlt->if_id = i;
qlt->vfl_length = MUX_QUEUE_LEVEL * sizeof(struct mux_lite_vfl);
qlt->reserved[0] = 0;
qlt->reserved[1] = 0;
qlt->vfl.nr_of_bytes = cpu_to_le32(session->ul_list.qlen);
/* Add QLT to the transfer list. */
skb_queue_tail(&ipc_mux->channel->ul_list,
ipc_mux->ul_adb.qlth_skb);
qlt_updated = true;
ipc_mux->ul_adb.qlth_skb = NULL;
}
if (qlt_updated)
/* Updates the TDs with ul_list */
(void)ipc_imem_ul_write_td(ipc_mux->imem);
return qlt_updated;
}
/* Checks the available credits for the specified session and returns
* number of packets for which credits are available.
*/
static int ipc_mux_ul_bytes_credits_check(struct iosm_mux *ipc_mux,
struct mux_session *session,
struct sk_buff_head *ul_list,
int max_nr_of_pkts)
{
int pkts_to_send = 0;
struct sk_buff *skb;
int credits = 0;
if (ipc_mux->ul_flow == MUX_UL_ON_CREDITS) {
credits = session->ul_flow_credits;
if (credits <= 0) {
dev_dbg(ipc_mux->dev,
"FC::if_id[%d] Insuff.Credits/Qlen:%d/%u",
session->if_id, session->ul_flow_credits,
session->ul_list.qlen); /* nr_of_bytes */
return 0;
}
} else {
credits = IPC_MEM_MUX_UL_FLOWCTRL_HIGH_B -
ipc_mux->ul_data_pend_bytes;
if (credits <= 0) {
ipc_mux_stop_tx_for_all_sessions(ipc_mux);
dev_dbg(ipc_mux->dev,
"if_id[%d] encod. fail Bytes: %llu, thresh: %d",
session->if_id, ipc_mux->ul_data_pend_bytes,
IPC_MEM_MUX_UL_FLOWCTRL_HIGH_B);
return 0;
}
}
/* Check if there are enough credits/bytes available to send the
* requested max_nr_of_pkts. Otherwise restrict the nr_of_pkts
* depending on available credits.
*/
skb_queue_walk(ul_list, skb)
{
if (!(credits >= skb->len && pkts_to_send < max_nr_of_pkts))
break;
credits -= skb->len;
pkts_to_send++;
}
return pkts_to_send;
}
/* Encode the UL IP packet according to Lite spec. */
static int ipc_mux_ul_adgh_encode(struct iosm_mux *ipc_mux, int session_id,
struct mux_session *session,
struct sk_buff_head *ul_list,
struct mux_adb *adb, int nr_of_pkts)
{
int offset = sizeof(struct mux_adgh);
int adb_updated = -EINVAL;
struct sk_buff *src_skb;
int aligned_size = 0;
int nr_of_skb = 0;
u32 pad_len = 0;
/* Re-calculate the number of packets depending on number of bytes to be
* processed/available credits.
*/
nr_of_pkts = ipc_mux_ul_bytes_credits_check(ipc_mux, session, ul_list,
nr_of_pkts);
/* If calculated nr_of_pkts from available credits is <= 0
* then nothing to do.
*/
if (nr_of_pkts <= 0)
return 0;
/* Read configured UL head_pad_length for session.*/
if (session->ul_head_pad_len > IPC_MEM_DL_ETH_OFFSET)
pad_len = session->ul_head_pad_len - IPC_MEM_DL_ETH_OFFSET;
/* Process all pending UL packets for this session
* depending on the allocated datagram table size.
*/
while (nr_of_pkts > 0) {
/* get destination skb allocated */
if (ipc_mux_ul_adb_allocate(ipc_mux, adb, &ipc_mux->size_needed,
IOSM_AGGR_MUX_SIG_ADGH)) {
dev_err(ipc_mux->dev, "no reserved memory for ADGH");
return -ENOMEM;
}
/* Peek at the head of the list. */
src_skb = skb_peek(ul_list);
if (!src_skb) {
dev_err(ipc_mux->dev,
"skb peek return NULL with count : %d",
nr_of_pkts);
break;
}
/* Calculate the memory value. */
aligned_size = ALIGN((pad_len + src_skb->len), 4);
ipc_mux->size_needed = sizeof(struct mux_adgh) + aligned_size;
if (ipc_mux->size_needed > adb->size) {
dev_dbg(ipc_mux->dev, "size needed %d, adgh size %d",
ipc_mux->size_needed, adb->size);
/* Return 1 if any IP packet is added to the transfer
* list.
*/
return nr_of_skb ? 1 : 0;
}
/* Add buffer (without head padding to next pending transfer) */
memcpy(adb->buf + offset + pad_len, src_skb->data,
src_skb->len);
adb->adgh->signature = cpu_to_le32(IOSM_AGGR_MUX_SIG_ADGH);
adb->adgh->if_id = session_id;
adb->adgh->length =
cpu_to_le16(sizeof(struct mux_adgh) + pad_len +
src_skb->len);
adb->adgh->service_class = src_skb->priority;
adb->adgh->next_count = --nr_of_pkts;
adb->dg_cnt_total++;
adb->payload_size += src_skb->len;
if (ipc_mux->ul_flow == MUX_UL_ON_CREDITS)
/* Decrement the credit value as we are processing the
* datagram from the UL list.
*/
session->ul_flow_credits -= src_skb->len;
/* Remove the processed elements and free it. */
src_skb = skb_dequeue(ul_list);
dev_kfree_skb(src_skb);
nr_of_skb++;
ipc_mux_ul_adgh_finish(ipc_mux);
}
if (nr_of_skb) {
/* Send QLT info to modem if pending bytes > high watermark
* in case of mux lite
*/
if (ipc_mux->ul_flow == MUX_UL_ON_CREDITS ||
ipc_mux->ul_data_pend_bytes >=
IPC_MEM_MUX_UL_FLOWCTRL_LOW_B)
adb_updated = ipc_mux_lite_send_qlt(ipc_mux);
else
adb_updated = 1;
/* Updates the TDs with ul_list */
(void)ipc_imem_ul_write_td(ipc_mux->imem);
}
return adb_updated;
}
/**
* ipc_mux_ul_adb_update_ql - Adds Queue Level Table and Queue Level to ADB
* @ipc_mux: pointer to MUX instance data
* @p_adb: pointer to UL aggegated data block
* @session_id: session id
* @qlth_n_ql_size: Length (in bytes) of the datagram table
* @ul_list: pointer to skb buffer head
*/
void ipc_mux_ul_adb_update_ql(struct iosm_mux *ipc_mux, struct mux_adb *p_adb,
int session_id, int qlth_n_ql_size,
struct sk_buff_head *ul_list)
{
int qlevel = ul_list->qlen;
struct mux_qlth *p_qlt;
p_qlt = (struct mux_qlth *)p_adb->pp_qlt[session_id];
/* Initialize QLTH if not been done */
if (p_adb->qlt_updated[session_id] == 0) {
p_qlt->signature = cpu_to_le32(MUX_SIG_QLTH);
p_qlt->if_id = session_id;
p_qlt->table_length = cpu_to_le16(qlth_n_ql_size);
p_qlt->reserved = 0;
p_qlt->reserved2 = 0;
}
/* Update Queue Level information always */
p_qlt->ql.nr_of_bytes = cpu_to_le32(qlevel);
p_adb->qlt_updated[session_id] = 1;
}
/* Update the next table index. */
static int mux_ul_dg_update_tbl_index(struct iosm_mux *ipc_mux,
int session_id,
struct sk_buff_head *ul_list,
struct mux_adth_dg *dg,
int aligned_size,
u32 qlth_n_ql_size,
struct mux_adb *adb,
struct sk_buff *src_skb)
{
ipc_mux_ul_adb_update_ql(ipc_mux, adb, session_id,
qlth_n_ql_size, ul_list);
ipc_mux_ul_adb_finish(ipc_mux);
if (ipc_mux_ul_adb_allocate(ipc_mux, adb, &ipc_mux->size_needed,
IOSM_AGGR_MUX_SIG_ADBH))
return -ENOMEM;
ipc_mux->size_needed = le32_to_cpu(adb->adbh->block_length);
ipc_mux->size_needed += offsetof(struct mux_adth, dg);
ipc_mux->size_needed += qlth_n_ql_size;
ipc_mux->size_needed += sizeof(*dg) + aligned_size;
return 0;
}
/* Process encode session UL data. */
static int mux_ul_dg_encode(struct iosm_mux *ipc_mux, struct mux_adb *adb,
struct mux_adth_dg *dg,
struct sk_buff_head *ul_list,
struct sk_buff *src_skb, int session_id,
int pkt_to_send, u32 qlth_n_ql_size,
int *out_offset, int head_pad_len)
{
int aligned_size;
int offset = *out_offset;
unsigned long flags;
int nr_of_skb = 0;
while (pkt_to_send > 0) {
/* Peek at the head of the list. */
src_skb = skb_peek(ul_list);
if (!src_skb) {
dev_err(ipc_mux->dev,
"skb peek return NULL with count : %d",
pkt_to_send);
return -1;
}
aligned_size = ALIGN((head_pad_len + src_skb->len), 4);
ipc_mux->size_needed += sizeof(*dg) + aligned_size;
if (ipc_mux->size_needed > adb->size ||
((ipc_mux->size_needed + ipc_mux->ul_data_pend_bytes) >=
IPC_MEM_MUX_UL_FLOWCTRL_HIGH_B)) {
*adb->next_table_index = offset;
if (mux_ul_dg_update_tbl_index(ipc_mux, session_id,
ul_list, dg,
aligned_size,
qlth_n_ql_size, adb,
src_skb) < 0)
return -ENOMEM;
nr_of_skb = 0;
offset = le32_to_cpu(adb->adbh->block_length);
/* Load pointer to next available datagram entry */
dg = adb->dg[session_id] + adb->dg_count[session_id];
}
/* Add buffer without head padding to next pending transfer. */
memcpy(adb->buf + offset + head_pad_len,
src_skb->data, src_skb->len);
/* Setup datagram entry. */
dg->datagram_index = cpu_to_le32(offset);
dg->datagram_length = cpu_to_le16(src_skb->len + head_pad_len);
dg->service_class = (((struct sk_buff *)src_skb)->priority);
dg->reserved = 0;
adb->dg_cnt_total++;
adb->payload_size += le16_to_cpu(dg->datagram_length);
dg++;
adb->dg_count[session_id]++;
offset += aligned_size;
/* Remove the processed elements and free it. */
spin_lock_irqsave(&ul_list->lock, flags);
src_skb = __skb_dequeue(ul_list);
spin_unlock_irqrestore(&ul_list->lock, flags);
dev_kfree_skb(src_skb);
nr_of_skb++;
pkt_to_send--;
}
*out_offset = offset;
return nr_of_skb;
}
/* Process encode session UL data to ADB. */
static int mux_ul_adb_encode(struct iosm_mux *ipc_mux, int session_id,
struct mux_session *session,
struct sk_buff_head *ul_list, struct mux_adb *adb,
int pkt_to_send)
{
int adb_updated = -EINVAL;
int head_pad_len, offset;
struct sk_buff *src_skb = NULL;
struct mux_adth_dg *dg;
u32 qlth_n_ql_size;
/* If any of the opened session has set Flow Control ON then limit the
* UL data to mux_flow_ctrl_high_thresh_b bytes
*/
if (ipc_mux->ul_data_pend_bytes >=
IPC_MEM_MUX_UL_FLOWCTRL_HIGH_B) {
ipc_mux_stop_tx_for_all_sessions(ipc_mux);
return adb_updated;
}
qlth_n_ql_size = offsetof(struct mux_qlth, ql) +
MUX_QUEUE_LEVEL * sizeof(struct mux_qlth_ql);
head_pad_len = session->ul_head_pad_len;
if (session->ul_head_pad_len > IPC_MEM_DL_ETH_OFFSET)
head_pad_len = session->ul_head_pad_len - IPC_MEM_DL_ETH_OFFSET;
if (ipc_mux_ul_adb_allocate(ipc_mux, adb, &ipc_mux->size_needed,
IOSM_AGGR_MUX_SIG_ADBH))
return -ENOMEM;
offset = le32_to_cpu(adb->adbh->block_length);
if (ipc_mux->size_needed == 0)
ipc_mux->size_needed = offset;
/* Calculate the size needed for ADTH, QLTH and QL*/
if (adb->dg_count[session_id] == 0) {
ipc_mux->size_needed += offsetof(struct mux_adth, dg);
ipc_mux->size_needed += qlth_n_ql_size;
}
dg = adb->dg[session_id] + adb->dg_count[session_id];
if (mux_ul_dg_encode(ipc_mux, adb, dg, ul_list, src_skb,
session_id, pkt_to_send, qlth_n_ql_size, &offset,
head_pad_len) > 0) {
adb_updated = 1;
*adb->next_table_index = offset;
ipc_mux_ul_adb_update_ql(ipc_mux, adb, session_id,
qlth_n_ql_size, ul_list);
adb->adbh->block_length = cpu_to_le32(offset);
}
return adb_updated;
}
bool ipc_mux_ul_data_encode(struct iosm_mux *ipc_mux)
{
struct sk_buff_head *ul_list;
struct mux_session *session;
int updated = 0;
int session_id;
int dg_n;
int i;
if (!ipc_mux || ipc_mux->state != MUX_S_ACTIVE ||
ipc_mux->adb_prep_ongoing)
return false;
ipc_mux->adb_prep_ongoing = true;
for (i = 0; i < IPC_MEM_MUX_IP_SESSION_ENTRIES; i++) {
session_id = ipc_mux->rr_next_session;
session = &ipc_mux->session[session_id];
/* Go to next handle rr_next_session overflow */
ipc_mux->rr_next_session++;
if (ipc_mux->rr_next_session >= IPC_MEM_MUX_IP_SESSION_ENTRIES)
ipc_mux->rr_next_session = 0;
if (!session->wwan || session->flow_ctl_mask ||
session->net_tx_stop)
continue;
ul_list = &session->ul_list;
/* Is something pending in UL and flow ctrl off */
dg_n = skb_queue_len(ul_list);
if (dg_n > MUX_MAX_UL_DG_ENTRIES)
dg_n = MUX_MAX_UL_DG_ENTRIES;
if (dg_n == 0)
/* Nothing to do for ipc_mux session
* -> try next session id.
*/
continue;
if (ipc_mux->protocol == MUX_LITE)
updated = ipc_mux_ul_adgh_encode(ipc_mux, session_id,
session, ul_list,
&ipc_mux->ul_adb,
dg_n);
else
updated = mux_ul_adb_encode(ipc_mux, session_id,
session, ul_list,
&ipc_mux->ul_adb,
dg_n);
}
ipc_mux->adb_prep_ongoing = false;
return updated == 1;
}
/* Calculates the Payload from any given ADB. */
static int ipc_mux_get_payload_from_adb(struct iosm_mux *ipc_mux,
struct mux_adbh *p_adbh)
{
struct mux_adth_dg *dg;
struct mux_adth *adth;
u32 payload_size = 0;
u32 next_table_idx;
int nr_of_dg, i;
/* Process the aggregated datagram tables. */
next_table_idx = le32_to_cpu(p_adbh->first_table_index);
if (next_table_idx < sizeof(struct mux_adbh)) {
dev_err(ipc_mux->dev, "unexpected empty ADB");
return payload_size;
}
while (next_table_idx != 0) {
/* Get the reference to the table header. */
adth = (struct mux_adth *)((u8 *)p_adbh + next_table_idx);
if (adth->signature == cpu_to_le32(IOSM_AGGR_MUX_SIG_ADTH)) {
nr_of_dg = (le16_to_cpu(adth->table_length) -
sizeof(struct mux_adth)) /
sizeof(struct mux_adth_dg);
if (nr_of_dg <= 0)
return payload_size;
dg = adth->dg;
for (i = 0; i < nr_of_dg; i++, dg++) {
if (le32_to_cpu(dg->datagram_index) <
sizeof(struct mux_adbh)) {
return payload_size;
}
payload_size +=
le16_to_cpu(dg->datagram_length);
}
}
next_table_idx = le32_to_cpu(adth->next_table_index);
}
return payload_size;
}
void ipc_mux_ul_encoded_process(struct iosm_mux *ipc_mux, struct sk_buff *skb)
{
union mux_type_header hr;
u16 adgh_len;
int payload;
if (ipc_mux->protocol == MUX_LITE) {
hr.adgh = (struct mux_adgh *)skb->data;
adgh_len = le16_to_cpu(hr.adgh->length);
if (hr.adgh->signature == cpu_to_le32(IOSM_AGGR_MUX_SIG_ADGH) &&
ipc_mux->ul_flow == MUX_UL)
ipc_mux->ul_data_pend_bytes =
ipc_mux->ul_data_pend_bytes - adgh_len;
} else {
hr.adbh = (struct mux_adbh *)(skb->data);
payload = ipc_mux_get_payload_from_adb(ipc_mux, hr.adbh);
ipc_mux->ul_data_pend_bytes -= payload;
}
if (ipc_mux->ul_flow == MUX_UL)
dev_dbg(ipc_mux->dev, "ul_data_pend_bytes: %lld",
ipc_mux->ul_data_pend_bytes);
/* Reset the skb settings. */
skb_trim(skb, 0);
/* Add the consumed ADB to the free list. */
skb_queue_tail((&ipc_mux->ul_adb.free_list), skb);
}
/* Start the NETIF uplink send transfer in MUX mode. */
static int ipc_mux_tq_ul_trigger_encode(struct iosm_imem *ipc_imem, int arg,
void *msg, size_t size)
{
struct iosm_mux *ipc_mux = ipc_imem->mux;
bool ul_data_pend = false;
/* Add session UL data to a ADB and ADGH */
ul_data_pend = ipc_mux_ul_data_encode(ipc_mux);
if (ul_data_pend) {
if (ipc_mux->protocol == MUX_AGGREGATION)
ipc_imem_adb_timer_start(ipc_mux->imem);
/* Delay the doorbell irq */
ipc_imem_td_update_timer_start(ipc_mux->imem);
}
/* reset the debounce flag */
ipc_mux->ev_mux_net_transmit_pending = false;
return 0;
}
int ipc_mux_ul_trigger_encode(struct iosm_mux *ipc_mux, int if_id,
struct sk_buff *skb)
{
struct mux_session *session = &ipc_mux->session[if_id];
int ret = -EINVAL;
if (ipc_mux->channel &&
ipc_mux->channel->state != IMEM_CHANNEL_ACTIVE) {
dev_err(ipc_mux->dev,
"channel state is not IMEM_CHANNEL_ACTIVE");
goto out;
}
if (!session->wwan) {
dev_err(ipc_mux->dev, "session net ID is NULL");
ret = -EFAULT;
goto out;
}
/* Session is under flow control.
* Check if packet can be queued in session list, if not
* suspend net tx
*/
if (skb_queue_len(&session->ul_list) >=
(session->net_tx_stop ?
IPC_MEM_MUX_UL_SESS_FCON_THRESHOLD :
(IPC_MEM_MUX_UL_SESS_FCON_THRESHOLD *
IPC_MEM_MUX_UL_SESS_FCOFF_THRESHOLD_FACTOR))) {
ipc_mux_netif_tx_flowctrl(session, session->if_id, true);
ret = -EBUSY;
goto out;
}
/* Add skb to the uplink skb accumulator. */
skb_queue_tail(&session->ul_list, skb);
/* Inform the IPC kthread to pass uplink IP packets to CP. */
if (!ipc_mux->ev_mux_net_transmit_pending) {
ipc_mux->ev_mux_net_transmit_pending = true;
ret = ipc_task_queue_send_task(ipc_mux->imem,
ipc_mux_tq_ul_trigger_encode, 0,
NULL, 0, false);
if (ret)
goto out;
}
dev_dbg(ipc_mux->dev, "mux ul if[%d] qlen=%d/%u, len=%d/%d, prio=%d",
if_id, skb_queue_len(&session->ul_list), session->ul_list.qlen,
skb->len, skb->truesize, skb->priority);
ret = 0;
out:
return ret;
}
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