OpenCloudOS-Kernel/drivers/net/wireless/ath/wcn36xx/dxe.c

806 lines
21 KiB
C

/*
* Copyright (c) 2013 Eugene Krasnikov <k.eugene.e@gmail.com>
*
* Permission to use, copy, modify, and/or distribute this software for any
* purpose with or without fee is hereby granted, provided that the above
* copyright notice and this permission notice appear in all copies.
*
* THE SOFTWARE IS PROVIDED "AS IS" AND THE AUTHOR DISCLAIMS ALL WARRANTIES
* WITH REGARD TO THIS SOFTWARE INCLUDING ALL IMPLIED WARRANTIES OF
* MERCHANTABILITY AND FITNESS. IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY
* SPECIAL, DIRECT, INDIRECT, OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES
* WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR PROFITS, WHETHER IN AN ACTION
* OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT OF OR IN
* CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE.
*/
/* DXE - DMA transfer engine
* we have 2 channels(High prio and Low prio) for TX and 2 channels for RX.
* through low channels data packets are transfered
* through high channels managment packets are transfered
*/
#define pr_fmt(fmt) KBUILD_MODNAME ": " fmt
#include <linux/interrupt.h>
#include "wcn36xx.h"
#include "txrx.h"
void *wcn36xx_dxe_get_next_bd(struct wcn36xx *wcn, bool is_low)
{
struct wcn36xx_dxe_ch *ch = is_low ?
&wcn->dxe_tx_l_ch :
&wcn->dxe_tx_h_ch;
return ch->head_blk_ctl->bd_cpu_addr;
}
static void wcn36xx_dxe_write_register(struct wcn36xx *wcn, int addr, int data)
{
wcn36xx_dbg(WCN36XX_DBG_DXE,
"wcn36xx_dxe_write_register: addr=%x, data=%x\n",
addr, data);
writel(data, wcn->mmio + addr);
}
static void wcn36xx_dxe_read_register(struct wcn36xx *wcn, int addr, int *data)
{
*data = readl(wcn->mmio + addr);
wcn36xx_dbg(WCN36XX_DBG_DXE,
"wcn36xx_dxe_read_register: addr=%x, data=%x\n",
addr, *data);
}
static void wcn36xx_dxe_free_ctl_block(struct wcn36xx_dxe_ch *ch)
{
struct wcn36xx_dxe_ctl *ctl = ch->head_blk_ctl, *next;
int i;
for (i = 0; i < ch->desc_num && ctl; i++) {
next = ctl->next;
kfree(ctl);
ctl = next;
}
}
static int wcn36xx_dxe_allocate_ctl_block(struct wcn36xx_dxe_ch *ch)
{
struct wcn36xx_dxe_ctl *prev_ctl = NULL;
struct wcn36xx_dxe_ctl *cur_ctl = NULL;
int i;
for (i = 0; i < ch->desc_num; i++) {
cur_ctl = kzalloc(sizeof(*cur_ctl), GFP_KERNEL);
if (!cur_ctl)
goto out_fail;
cur_ctl->ctl_blk_order = i;
if (i == 0) {
ch->head_blk_ctl = cur_ctl;
ch->tail_blk_ctl = cur_ctl;
} else if (ch->desc_num - 1 == i) {
prev_ctl->next = cur_ctl;
cur_ctl->next = ch->head_blk_ctl;
} else {
prev_ctl->next = cur_ctl;
}
prev_ctl = cur_ctl;
}
return 0;
out_fail:
wcn36xx_dxe_free_ctl_block(ch);
return -ENOMEM;
}
int wcn36xx_dxe_alloc_ctl_blks(struct wcn36xx *wcn)
{
int ret;
wcn->dxe_tx_l_ch.ch_type = WCN36XX_DXE_CH_TX_L;
wcn->dxe_tx_h_ch.ch_type = WCN36XX_DXE_CH_TX_H;
wcn->dxe_rx_l_ch.ch_type = WCN36XX_DXE_CH_RX_L;
wcn->dxe_rx_h_ch.ch_type = WCN36XX_DXE_CH_RX_H;
wcn->dxe_tx_l_ch.desc_num = WCN36XX_DXE_CH_DESC_NUMB_TX_L;
wcn->dxe_tx_h_ch.desc_num = WCN36XX_DXE_CH_DESC_NUMB_TX_H;
wcn->dxe_rx_l_ch.desc_num = WCN36XX_DXE_CH_DESC_NUMB_RX_L;
wcn->dxe_rx_h_ch.desc_num = WCN36XX_DXE_CH_DESC_NUMB_RX_H;
wcn->dxe_tx_l_ch.dxe_wq = WCN36XX_DXE_WQ_TX_L;
wcn->dxe_tx_h_ch.dxe_wq = WCN36XX_DXE_WQ_TX_H;
wcn->dxe_tx_l_ch.ctrl_bd = WCN36XX_DXE_CTRL_TX_L_BD;
wcn->dxe_tx_h_ch.ctrl_bd = WCN36XX_DXE_CTRL_TX_H_BD;
wcn->dxe_tx_l_ch.ctrl_skb = WCN36XX_DXE_CTRL_TX_L_SKB;
wcn->dxe_tx_h_ch.ctrl_skb = WCN36XX_DXE_CTRL_TX_H_SKB;
wcn->dxe_tx_l_ch.reg_ctrl = WCN36XX_DXE_REG_CTL_TX_L;
wcn->dxe_tx_h_ch.reg_ctrl = WCN36XX_DXE_REG_CTL_TX_H;
wcn->dxe_tx_l_ch.def_ctrl = WCN36XX_DXE_CH_DEFAULT_CTL_TX_L;
wcn->dxe_tx_h_ch.def_ctrl = WCN36XX_DXE_CH_DEFAULT_CTL_TX_H;
/* DXE control block allocation */
ret = wcn36xx_dxe_allocate_ctl_block(&wcn->dxe_tx_l_ch);
if (ret)
goto out_err;
ret = wcn36xx_dxe_allocate_ctl_block(&wcn->dxe_tx_h_ch);
if (ret)
goto out_err;
ret = wcn36xx_dxe_allocate_ctl_block(&wcn->dxe_rx_l_ch);
if (ret)
goto out_err;
ret = wcn36xx_dxe_allocate_ctl_block(&wcn->dxe_rx_h_ch);
if (ret)
goto out_err;
/* Initialize SMSM state Clear TX Enable RING EMPTY STATE */
ret = wcn->ctrl_ops->smsm_change_state(
WCN36XX_SMSM_WLAN_TX_ENABLE,
WCN36XX_SMSM_WLAN_TX_RINGS_EMPTY);
return 0;
out_err:
wcn36xx_err("Failed to allocate DXE control blocks\n");
wcn36xx_dxe_free_ctl_blks(wcn);
return -ENOMEM;
}
void wcn36xx_dxe_free_ctl_blks(struct wcn36xx *wcn)
{
wcn36xx_dxe_free_ctl_block(&wcn->dxe_tx_l_ch);
wcn36xx_dxe_free_ctl_block(&wcn->dxe_tx_h_ch);
wcn36xx_dxe_free_ctl_block(&wcn->dxe_rx_l_ch);
wcn36xx_dxe_free_ctl_block(&wcn->dxe_rx_h_ch);
}
static int wcn36xx_dxe_init_descs(struct wcn36xx_dxe_ch *wcn_ch)
{
struct wcn36xx_dxe_desc *cur_dxe = NULL;
struct wcn36xx_dxe_desc *prev_dxe = NULL;
struct wcn36xx_dxe_ctl *cur_ctl = NULL;
size_t size;
int i;
size = wcn_ch->desc_num * sizeof(struct wcn36xx_dxe_desc);
wcn_ch->cpu_addr = dma_alloc_coherent(NULL, size, &wcn_ch->dma_addr,
GFP_KERNEL);
if (!wcn_ch->cpu_addr)
return -ENOMEM;
memset(wcn_ch->cpu_addr, 0, size);
cur_dxe = (struct wcn36xx_dxe_desc *)wcn_ch->cpu_addr;
cur_ctl = wcn_ch->head_blk_ctl;
for (i = 0; i < wcn_ch->desc_num; i++) {
cur_ctl->desc = cur_dxe;
cur_ctl->desc_phy_addr = wcn_ch->dma_addr +
i * sizeof(struct wcn36xx_dxe_desc);
switch (wcn_ch->ch_type) {
case WCN36XX_DXE_CH_TX_L:
cur_dxe->ctrl = WCN36XX_DXE_CTRL_TX_L;
cur_dxe->dst_addr_l = WCN36XX_DXE_WQ_TX_L;
break;
case WCN36XX_DXE_CH_TX_H:
cur_dxe->ctrl = WCN36XX_DXE_CTRL_TX_H;
cur_dxe->dst_addr_l = WCN36XX_DXE_WQ_TX_H;
break;
case WCN36XX_DXE_CH_RX_L:
cur_dxe->ctrl = WCN36XX_DXE_CTRL_RX_L;
cur_dxe->src_addr_l = WCN36XX_DXE_WQ_RX_L;
break;
case WCN36XX_DXE_CH_RX_H:
cur_dxe->ctrl = WCN36XX_DXE_CTRL_RX_H;
cur_dxe->src_addr_l = WCN36XX_DXE_WQ_RX_H;
break;
}
if (0 == i) {
cur_dxe->phy_next_l = 0;
} else if ((0 < i) && (i < wcn_ch->desc_num - 1)) {
prev_dxe->phy_next_l =
cur_ctl->desc_phy_addr;
} else if (i == (wcn_ch->desc_num - 1)) {
prev_dxe->phy_next_l =
cur_ctl->desc_phy_addr;
cur_dxe->phy_next_l =
wcn_ch->head_blk_ctl->desc_phy_addr;
}
cur_ctl = cur_ctl->next;
prev_dxe = cur_dxe;
cur_dxe++;
}
return 0;
}
static void wcn36xx_dxe_init_tx_bd(struct wcn36xx_dxe_ch *ch,
struct wcn36xx_dxe_mem_pool *pool)
{
int i, chunk_size = pool->chunk_size;
dma_addr_t bd_phy_addr = pool->phy_addr;
void *bd_cpu_addr = pool->virt_addr;
struct wcn36xx_dxe_ctl *cur = ch->head_blk_ctl;
for (i = 0; i < ch->desc_num; i++) {
/* Only every second dxe needs a bd pointer,
the other will point to the skb data */
if (!(i & 1)) {
cur->bd_phy_addr = bd_phy_addr;
cur->bd_cpu_addr = bd_cpu_addr;
bd_phy_addr += chunk_size;
bd_cpu_addr += chunk_size;
} else {
cur->bd_phy_addr = 0;
cur->bd_cpu_addr = NULL;
}
cur = cur->next;
}
}
static int wcn36xx_dxe_enable_ch_int(struct wcn36xx *wcn, u16 wcn_ch)
{
int reg_data = 0;
wcn36xx_dxe_read_register(wcn,
WCN36XX_DXE_INT_MASK_REG,
&reg_data);
reg_data |= wcn_ch;
wcn36xx_dxe_write_register(wcn,
WCN36XX_DXE_INT_MASK_REG,
(int)reg_data);
return 0;
}
static int wcn36xx_dxe_fill_skb(struct wcn36xx_dxe_ctl *ctl)
{
struct wcn36xx_dxe_desc *dxe = ctl->desc;
struct sk_buff *skb;
skb = alloc_skb(WCN36XX_PKT_SIZE, GFP_ATOMIC);
if (skb == NULL)
return -ENOMEM;
dxe->dst_addr_l = dma_map_single(NULL,
skb_tail_pointer(skb),
WCN36XX_PKT_SIZE,
DMA_FROM_DEVICE);
ctl->skb = skb;
return 0;
}
static int wcn36xx_dxe_ch_alloc_skb(struct wcn36xx *wcn,
struct wcn36xx_dxe_ch *wcn_ch)
{
int i;
struct wcn36xx_dxe_ctl *cur_ctl = NULL;
cur_ctl = wcn_ch->head_blk_ctl;
for (i = 0; i < wcn_ch->desc_num; i++) {
wcn36xx_dxe_fill_skb(cur_ctl);
cur_ctl = cur_ctl->next;
}
return 0;
}
static void wcn36xx_dxe_ch_free_skbs(struct wcn36xx *wcn,
struct wcn36xx_dxe_ch *wcn_ch)
{
struct wcn36xx_dxe_ctl *cur = wcn_ch->head_blk_ctl;
int i;
for (i = 0; i < wcn_ch->desc_num; i++) {
kfree_skb(cur->skb);
cur = cur->next;
}
}
void wcn36xx_dxe_tx_ack_ind(struct wcn36xx *wcn, u32 status)
{
struct ieee80211_tx_info *info;
struct sk_buff *skb;
unsigned long flags;
spin_lock_irqsave(&wcn->dxe_lock, flags);
skb = wcn->tx_ack_skb;
wcn->tx_ack_skb = NULL;
spin_unlock_irqrestore(&wcn->dxe_lock, flags);
if (!skb) {
wcn36xx_warn("Spurious TX complete indication\n");
return;
}
info = IEEE80211_SKB_CB(skb);
if (status == 1)
info->flags |= IEEE80211_TX_STAT_ACK;
wcn36xx_dbg(WCN36XX_DBG_DXE, "dxe tx ack status: %d\n", status);
ieee80211_tx_status_irqsafe(wcn->hw, skb);
ieee80211_wake_queues(wcn->hw);
}
static void reap_tx_dxes(struct wcn36xx *wcn, struct wcn36xx_dxe_ch *ch)
{
struct wcn36xx_dxe_ctl *ctl = ch->tail_blk_ctl;
struct ieee80211_tx_info *info;
unsigned long flags;
/*
* Make at least one loop of do-while because in case ring is
* completely full head and tail are pointing to the same element
* and while-do will not make any cycles.
*/
do {
if (ctl->skb) {
dma_unmap_single(NULL, ctl->desc->src_addr_l,
ctl->skb->len, DMA_TO_DEVICE);
info = IEEE80211_SKB_CB(ctl->skb);
if (!(info->flags & IEEE80211_TX_CTL_REQ_TX_STATUS)) {
/* Keep frame until TX status comes */
ieee80211_free_txskb(wcn->hw, ctl->skb);
}
spin_lock_irqsave(&ctl->skb_lock, flags);
if (wcn->queues_stopped) {
wcn->queues_stopped = false;
ieee80211_wake_queues(wcn->hw);
}
spin_unlock_irqrestore(&ctl->skb_lock, flags);
ctl->skb = NULL;
}
ctl = ctl->next;
} while (ctl != ch->head_blk_ctl &&
!(ctl->desc->ctrl & WCN36XX_DXE_CTRL_VALID_MASK));
ch->tail_blk_ctl = ctl;
}
static irqreturn_t wcn36xx_irq_tx_complete(int irq, void *dev)
{
struct wcn36xx *wcn = (struct wcn36xx *)dev;
int int_src, int_reason;
wcn36xx_dxe_read_register(wcn, WCN36XX_DXE_INT_SRC_RAW_REG, &int_src);
if (int_src & WCN36XX_INT_MASK_CHAN_TX_H) {
wcn36xx_dxe_read_register(wcn,
WCN36XX_DXE_CH_STATUS_REG_ADDR_TX_H,
&int_reason);
/* TODO: Check int_reason */
wcn36xx_dxe_write_register(wcn,
WCN36XX_DXE_0_INT_CLR,
WCN36XX_INT_MASK_CHAN_TX_H);
wcn36xx_dxe_write_register(wcn, WCN36XX_DXE_0_INT_ED_CLR,
WCN36XX_INT_MASK_CHAN_TX_H);
wcn36xx_dbg(WCN36XX_DBG_DXE, "dxe tx ready high\n");
reap_tx_dxes(wcn, &wcn->dxe_tx_h_ch);
}
if (int_src & WCN36XX_INT_MASK_CHAN_TX_L) {
wcn36xx_dxe_read_register(wcn,
WCN36XX_DXE_CH_STATUS_REG_ADDR_TX_L,
&int_reason);
/* TODO: Check int_reason */
wcn36xx_dxe_write_register(wcn,
WCN36XX_DXE_0_INT_CLR,
WCN36XX_INT_MASK_CHAN_TX_L);
wcn36xx_dxe_write_register(wcn, WCN36XX_DXE_0_INT_ED_CLR,
WCN36XX_INT_MASK_CHAN_TX_L);
wcn36xx_dbg(WCN36XX_DBG_DXE, "dxe tx ready low\n");
reap_tx_dxes(wcn, &wcn->dxe_tx_l_ch);
}
return IRQ_HANDLED;
}
static irqreturn_t wcn36xx_irq_rx_ready(int irq, void *dev)
{
struct wcn36xx *wcn = (struct wcn36xx *)dev;
disable_irq_nosync(wcn->rx_irq);
wcn36xx_dxe_rx_frame(wcn);
enable_irq(wcn->rx_irq);
return IRQ_HANDLED;
}
static int wcn36xx_dxe_request_irqs(struct wcn36xx *wcn)
{
int ret;
ret = request_irq(wcn->tx_irq, wcn36xx_irq_tx_complete,
IRQF_TRIGGER_HIGH, "wcn36xx_tx", wcn);
if (ret) {
wcn36xx_err("failed to alloc tx irq\n");
goto out_err;
}
ret = request_irq(wcn->rx_irq, wcn36xx_irq_rx_ready, IRQF_TRIGGER_HIGH,
"wcn36xx_rx", wcn);
if (ret) {
wcn36xx_err("failed to alloc rx irq\n");
goto out_txirq;
}
enable_irq_wake(wcn->rx_irq);
return 0;
out_txirq:
free_irq(wcn->tx_irq, wcn);
out_err:
return ret;
}
static int wcn36xx_rx_handle_packets(struct wcn36xx *wcn,
struct wcn36xx_dxe_ch *ch)
{
struct wcn36xx_dxe_ctl *ctl = ch->head_blk_ctl;
struct wcn36xx_dxe_desc *dxe = ctl->desc;
dma_addr_t dma_addr;
struct sk_buff *skb;
while (!(dxe->ctrl & WCN36XX_DXE_CTRL_VALID_MASK)) {
skb = ctl->skb;
dma_addr = dxe->dst_addr_l;
wcn36xx_dxe_fill_skb(ctl);
switch (ch->ch_type) {
case WCN36XX_DXE_CH_RX_L:
dxe->ctrl = WCN36XX_DXE_CTRL_RX_L;
wcn36xx_dxe_write_register(wcn, WCN36XX_DXE_ENCH_ADDR,
WCN36XX_DXE_INT_CH1_MASK);
break;
case WCN36XX_DXE_CH_RX_H:
dxe->ctrl = WCN36XX_DXE_CTRL_RX_H;
wcn36xx_dxe_write_register(wcn, WCN36XX_DXE_ENCH_ADDR,
WCN36XX_DXE_INT_CH3_MASK);
break;
default:
wcn36xx_warn("Unknown channel\n");
}
dma_unmap_single(NULL, dma_addr, WCN36XX_PKT_SIZE,
DMA_FROM_DEVICE);
wcn36xx_rx_skb(wcn, skb);
ctl = ctl->next;
dxe = ctl->desc;
}
ch->head_blk_ctl = ctl;
return 0;
}
void wcn36xx_dxe_rx_frame(struct wcn36xx *wcn)
{
int int_src;
wcn36xx_dxe_read_register(wcn, WCN36XX_DXE_INT_SRC_RAW_REG, &int_src);
/* RX_LOW_PRI */
if (int_src & WCN36XX_DXE_INT_CH1_MASK) {
wcn36xx_dxe_write_register(wcn, WCN36XX_DXE_0_INT_CLR,
WCN36XX_DXE_INT_CH1_MASK);
wcn36xx_rx_handle_packets(wcn, &(wcn->dxe_rx_l_ch));
}
/* RX_HIGH_PRI */
if (int_src & WCN36XX_DXE_INT_CH3_MASK) {
/* Clean up all the INT within this channel */
wcn36xx_dxe_write_register(wcn, WCN36XX_DXE_0_INT_CLR,
WCN36XX_DXE_INT_CH3_MASK);
wcn36xx_rx_handle_packets(wcn, &(wcn->dxe_rx_h_ch));
}
if (!int_src)
wcn36xx_warn("No DXE interrupt pending\n");
}
int wcn36xx_dxe_allocate_mem_pools(struct wcn36xx *wcn)
{
size_t s;
void *cpu_addr;
/* Allocate BD headers for MGMT frames */
/* Where this come from ask QC */
wcn->mgmt_mem_pool.chunk_size = WCN36XX_BD_CHUNK_SIZE +
16 - (WCN36XX_BD_CHUNK_SIZE % 8);
s = wcn->mgmt_mem_pool.chunk_size * WCN36XX_DXE_CH_DESC_NUMB_TX_H;
cpu_addr = dma_alloc_coherent(NULL, s, &wcn->mgmt_mem_pool.phy_addr,
GFP_KERNEL);
if (!cpu_addr)
goto out_err;
wcn->mgmt_mem_pool.virt_addr = cpu_addr;
memset(cpu_addr, 0, s);
/* Allocate BD headers for DATA frames */
/* Where this come from ask QC */
wcn->data_mem_pool.chunk_size = WCN36XX_BD_CHUNK_SIZE +
16 - (WCN36XX_BD_CHUNK_SIZE % 8);
s = wcn->data_mem_pool.chunk_size * WCN36XX_DXE_CH_DESC_NUMB_TX_L;
cpu_addr = dma_alloc_coherent(NULL, s, &wcn->data_mem_pool.phy_addr,
GFP_KERNEL);
if (!cpu_addr)
goto out_err;
wcn->data_mem_pool.virt_addr = cpu_addr;
memset(cpu_addr, 0, s);
return 0;
out_err:
wcn36xx_dxe_free_mem_pools(wcn);
wcn36xx_err("Failed to allocate BD mempool\n");
return -ENOMEM;
}
void wcn36xx_dxe_free_mem_pools(struct wcn36xx *wcn)
{
if (wcn->mgmt_mem_pool.virt_addr)
dma_free_coherent(NULL, wcn->mgmt_mem_pool.chunk_size *
WCN36XX_DXE_CH_DESC_NUMB_TX_H,
wcn->mgmt_mem_pool.virt_addr,
wcn->mgmt_mem_pool.phy_addr);
if (wcn->data_mem_pool.virt_addr) {
dma_free_coherent(NULL, wcn->data_mem_pool.chunk_size *
WCN36XX_DXE_CH_DESC_NUMB_TX_L,
wcn->data_mem_pool.virt_addr,
wcn->data_mem_pool.phy_addr);
}
}
int wcn36xx_dxe_tx_frame(struct wcn36xx *wcn,
struct wcn36xx_vif *vif_priv,
struct sk_buff *skb,
bool is_low)
{
struct wcn36xx_dxe_ctl *ctl = NULL;
struct wcn36xx_dxe_desc *desc = NULL;
struct wcn36xx_dxe_ch *ch = NULL;
unsigned long flags;
ch = is_low ? &wcn->dxe_tx_l_ch : &wcn->dxe_tx_h_ch;
ctl = ch->head_blk_ctl;
spin_lock_irqsave(&ctl->next->skb_lock, flags);
/*
* If skb is not null that means that we reached the tail of the ring
* hence ring is full. Stop queues to let mac80211 back off until ring
* has an empty slot again.
*/
if (NULL != ctl->next->skb) {
ieee80211_stop_queues(wcn->hw);
wcn->queues_stopped = true;
spin_unlock_irqrestore(&ctl->next->skb_lock, flags);
return -EBUSY;
}
spin_unlock_irqrestore(&ctl->next->skb_lock, flags);
ctl->skb = NULL;
desc = ctl->desc;
/* Set source address of the BD we send */
desc->src_addr_l = ctl->bd_phy_addr;
desc->dst_addr_l = ch->dxe_wq;
desc->fr_len = sizeof(struct wcn36xx_tx_bd);
desc->ctrl = ch->ctrl_bd;
wcn36xx_dbg(WCN36XX_DBG_DXE, "DXE TX\n");
wcn36xx_dbg_dump(WCN36XX_DBG_DXE_DUMP, "DESC1 >>> ",
(char *)desc, sizeof(*desc));
wcn36xx_dbg_dump(WCN36XX_DBG_DXE_DUMP,
"BD >>> ", (char *)ctl->bd_cpu_addr,
sizeof(struct wcn36xx_tx_bd));
/* Set source address of the SKB we send */
ctl = ctl->next;
ctl->skb = skb;
desc = ctl->desc;
if (ctl->bd_cpu_addr) {
wcn36xx_err("bd_cpu_addr cannot be NULL for skb DXE\n");
return -EINVAL;
}
desc->src_addr_l = dma_map_single(NULL,
ctl->skb->data,
ctl->skb->len,
DMA_TO_DEVICE);
desc->dst_addr_l = ch->dxe_wq;
desc->fr_len = ctl->skb->len;
/* set dxe descriptor to VALID */
desc->ctrl = ch->ctrl_skb;
wcn36xx_dbg_dump(WCN36XX_DBG_DXE_DUMP, "DESC2 >>> ",
(char *)desc, sizeof(*desc));
wcn36xx_dbg_dump(WCN36XX_DBG_DXE_DUMP, "SKB >>> ",
(char *)ctl->skb->data, ctl->skb->len);
/* Move the head of the ring to the next empty descriptor */
ch->head_blk_ctl = ctl->next;
/*
* When connected and trying to send data frame chip can be in sleep
* mode and writing to the register will not wake up the chip. Instead
* notify chip about new frame through SMSM bus.
*/
if (is_low && vif_priv->pw_state == WCN36XX_BMPS) {
wcn->ctrl_ops->smsm_change_state(
0,
WCN36XX_SMSM_WLAN_TX_ENABLE);
} else {
/* indicate End Of Packet and generate interrupt on descriptor
* done.
*/
wcn36xx_dxe_write_register(wcn,
ch->reg_ctrl, ch->def_ctrl);
}
return 0;
}
int wcn36xx_dxe_init(struct wcn36xx *wcn)
{
int reg_data = 0, ret;
reg_data = WCN36XX_DXE_REG_RESET;
wcn36xx_dxe_write_register(wcn, WCN36XX_DXE_REG_CSR_RESET, reg_data);
/* Setting interrupt path */
reg_data = WCN36XX_DXE_CCU_INT;
wcn36xx_dxe_write_register(wcn, WCN36XX_DXE_REG_CCU_INT, reg_data);
/***************************************/
/* Init descriptors for TX LOW channel */
/***************************************/
wcn36xx_dxe_init_descs(&wcn->dxe_tx_l_ch);
wcn36xx_dxe_init_tx_bd(&wcn->dxe_tx_l_ch, &wcn->data_mem_pool);
/* Write channel head to a NEXT register */
wcn36xx_dxe_write_register(wcn, WCN36XX_DXE_CH_NEXT_DESC_ADDR_TX_L,
wcn->dxe_tx_l_ch.head_blk_ctl->desc_phy_addr);
/* Program DMA destination addr for TX LOW */
wcn36xx_dxe_write_register(wcn,
WCN36XX_DXE_CH_DEST_ADDR_TX_L,
WCN36XX_DXE_WQ_TX_L);
wcn36xx_dxe_read_register(wcn, WCN36XX_DXE_REG_CH_EN, &reg_data);
wcn36xx_dxe_enable_ch_int(wcn, WCN36XX_INT_MASK_CHAN_TX_L);
/***************************************/
/* Init descriptors for TX HIGH channel */
/***************************************/
wcn36xx_dxe_init_descs(&wcn->dxe_tx_h_ch);
wcn36xx_dxe_init_tx_bd(&wcn->dxe_tx_h_ch, &wcn->mgmt_mem_pool);
/* Write channel head to a NEXT register */
wcn36xx_dxe_write_register(wcn, WCN36XX_DXE_CH_NEXT_DESC_ADDR_TX_H,
wcn->dxe_tx_h_ch.head_blk_ctl->desc_phy_addr);
/* Program DMA destination addr for TX HIGH */
wcn36xx_dxe_write_register(wcn,
WCN36XX_DXE_CH_DEST_ADDR_TX_H,
WCN36XX_DXE_WQ_TX_H);
wcn36xx_dxe_read_register(wcn, WCN36XX_DXE_REG_CH_EN, &reg_data);
/* Enable channel interrupts */
wcn36xx_dxe_enable_ch_int(wcn, WCN36XX_INT_MASK_CHAN_TX_H);
/***************************************/
/* Init descriptors for RX LOW channel */
/***************************************/
wcn36xx_dxe_init_descs(&wcn->dxe_rx_l_ch);
/* For RX we need to preallocated buffers */
wcn36xx_dxe_ch_alloc_skb(wcn, &wcn->dxe_rx_l_ch);
/* Write channel head to a NEXT register */
wcn36xx_dxe_write_register(wcn, WCN36XX_DXE_CH_NEXT_DESC_ADDR_RX_L,
wcn->dxe_rx_l_ch.head_blk_ctl->desc_phy_addr);
/* Write DMA source address */
wcn36xx_dxe_write_register(wcn,
WCN36XX_DXE_CH_SRC_ADDR_RX_L,
WCN36XX_DXE_WQ_RX_L);
/* Program preallocated destination address */
wcn36xx_dxe_write_register(wcn,
WCN36XX_DXE_CH_DEST_ADDR_RX_L,
wcn->dxe_rx_l_ch.head_blk_ctl->desc->phy_next_l);
/* Enable default control registers */
wcn36xx_dxe_write_register(wcn,
WCN36XX_DXE_REG_CTL_RX_L,
WCN36XX_DXE_CH_DEFAULT_CTL_RX_L);
/* Enable channel interrupts */
wcn36xx_dxe_enable_ch_int(wcn, WCN36XX_INT_MASK_CHAN_RX_L);
/***************************************/
/* Init descriptors for RX HIGH channel */
/***************************************/
wcn36xx_dxe_init_descs(&wcn->dxe_rx_h_ch);
/* For RX we need to prealocat buffers */
wcn36xx_dxe_ch_alloc_skb(wcn, &wcn->dxe_rx_h_ch);
/* Write chanel head to a NEXT register */
wcn36xx_dxe_write_register(wcn, WCN36XX_DXE_CH_NEXT_DESC_ADDR_RX_H,
wcn->dxe_rx_h_ch.head_blk_ctl->desc_phy_addr);
/* Write DMA source address */
wcn36xx_dxe_write_register(wcn,
WCN36XX_DXE_CH_SRC_ADDR_RX_H,
WCN36XX_DXE_WQ_RX_H);
/* Program preallocated destination address */
wcn36xx_dxe_write_register(wcn,
WCN36XX_DXE_CH_DEST_ADDR_RX_H,
wcn->dxe_rx_h_ch.head_blk_ctl->desc->phy_next_l);
/* Enable default control registers */
wcn36xx_dxe_write_register(wcn,
WCN36XX_DXE_REG_CTL_RX_H,
WCN36XX_DXE_CH_DEFAULT_CTL_RX_H);
/* Enable channel interrupts */
wcn36xx_dxe_enable_ch_int(wcn, WCN36XX_INT_MASK_CHAN_RX_H);
ret = wcn36xx_dxe_request_irqs(wcn);
if (ret < 0)
goto out_err;
return 0;
out_err:
return ret;
}
void wcn36xx_dxe_deinit(struct wcn36xx *wcn)
{
free_irq(wcn->tx_irq, wcn);
free_irq(wcn->rx_irq, wcn);
if (wcn->tx_ack_skb) {
ieee80211_tx_status_irqsafe(wcn->hw, wcn->tx_ack_skb);
wcn->tx_ack_skb = NULL;
}
wcn36xx_dxe_ch_free_skbs(wcn, &wcn->dxe_rx_l_ch);
wcn36xx_dxe_ch_free_skbs(wcn, &wcn->dxe_rx_h_ch);
}