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android-kvm / linux / 5163953950ab63ce296398b013d9d16bf2b40940 / . / drivers / net / ethernet / aquantia / atlantic / hw_atl / hw_atl_utils_fw2x.c
blob: 4d4cfbc91e19cf658fccd181d037c876a864e8f2 [file] [log] [blame]
// SPDX-License-Identifier: GPL-2.0-only
/* Atlantic Network Driver
*
* Copyright (C) 2014-2019 aQuantia Corporation
* Copyright (C) 2019-2020 Marvell International Ltd.
*/
/* File hw_atl_utils_fw2x.c: Definition of firmware 2.x functions for
* Atlantic hardware abstraction layer.
*/
#include "../aq_hw.h"
#include "../aq_hw_utils.h"
#include "../aq_pci_func.h"
#include "../aq_ring.h"
#include "../aq_vec.h"
#include "../aq_nic.h"
#include "hw_atl_utils.h"
#include "hw_atl_llh.h"
#define HW_ATL_FW2X_MPI_LED_ADDR 0x31c
#define HW_ATL_FW2X_MPI_RPC_ADDR 0x334
#define HW_ATL_FW2X_MPI_MBOX_ADDR 0x360
#define HW_ATL_FW2X_MPI_EFUSE_ADDR 0x364
#define HW_ATL_FW2X_MPI_CONTROL_ADDR 0x368
#define HW_ATL_FW2X_MPI_CONTROL2_ADDR 0x36C
#define HW_ATL_FW2X_MPI_STATE_ADDR 0x370
#define HW_ATL_FW2X_MPI_STATE2_ADDR 0x374
#define HW_ATL_FW3X_EXT_CONTROL_ADDR 0x378
#define HW_ATL_FW3X_EXT_STATE_ADDR 0x37c
#define HW_ATL_FW3X_PTP_ADJ_LSW_ADDR 0x50a0
#define HW_ATL_FW3X_PTP_ADJ_MSW_ADDR 0x50a4
#define HW_ATL_FW2X_CAP_PAUSE BIT(CAPS_HI_PAUSE)
#define HW_ATL_FW2X_CAP_ASYM_PAUSE BIT(CAPS_HI_ASYMMETRIC_PAUSE)
#define HW_ATL_FW2X_CAP_SLEEP_PROXY BIT(CAPS_HI_SLEEP_PROXY)
#define HW_ATL_FW2X_CAP_WOL BIT(CAPS_HI_WOL)
#define HW_ATL_FW2X_CTRL_WAKE_ON_LINK BIT(CTRL_WAKE_ON_LINK)
#define HW_ATL_FW2X_CTRL_SLEEP_PROXY BIT(CTRL_SLEEP_PROXY)
#define HW_ATL_FW2X_CTRL_WOL BIT(CTRL_WOL)
#define HW_ATL_FW2X_CTRL_LINK_DROP BIT(CTRL_LINK_DROP)
#define HW_ATL_FW2X_CTRL_PAUSE BIT(CTRL_PAUSE)
#define HW_ATL_FW2X_CTRL_TEMPERATURE BIT(CTRL_TEMPERATURE)
#define HW_ATL_FW2X_CTRL_ASYMMETRIC_PAUSE BIT(CTRL_ASYMMETRIC_PAUSE)
#define HW_ATL_FW2X_CTRL_INT_LOOPBACK BIT(CTRL_INT_LOOPBACK)
#define HW_ATL_FW2X_CTRL_EXT_LOOPBACK BIT(CTRL_EXT_LOOPBACK)
#define HW_ATL_FW2X_CTRL_DOWNSHIFT BIT(CTRL_DOWNSHIFT)
#define HW_ATL_FW2X_CTRL_FORCE_RECONNECT BIT(CTRL_FORCE_RECONNECT)
#define HW_ATL_FW2X_CAP_EEE_1G_MASK BIT(CAPS_HI_1000BASET_FD_EEE)
#define HW_ATL_FW2X_CAP_EEE_2G5_MASK BIT(CAPS_HI_2P5GBASET_FD_EEE)
#define HW_ATL_FW2X_CAP_EEE_5G_MASK BIT(CAPS_HI_5GBASET_FD_EEE)
#define HW_ATL_FW2X_CAP_EEE_10G_MASK BIT(CAPS_HI_10GBASET_FD_EEE)
#define HW_ATL_FW2X_CAP_MACSEC BIT(CAPS_LO_MACSEC)
#define HAL_ATLANTIC_WOL_FILTERS_COUNT 8
#define HAL_ATLANTIC_UTILS_FW2X_MSG_WOL 0x0E
#define HW_ATL_FW_VER_LED 0x03010026U
#define HW_ATL_FW_VER_MEDIA_CONTROL 0x0301005aU
struct __packed fw2x_msg_wol_pattern {
u8 mask[16];
u32 crc;
};
struct __packed fw2x_msg_wol {
u32 msg_id;
u8 hw_addr[ETH_ALEN];
u8 magic_packet_enabled;
u8 filter_count;
struct fw2x_msg_wol_pattern filter[HAL_ATLANTIC_WOL_FILTERS_COUNT];
u8 link_up_enabled;
u8 link_down_enabled;
u16 reserved;
u32 link_up_timeout;
u32 link_down_timeout;
};
static int aq_fw2x_set_link_speed(struct aq_hw_s *self, u32 speed);
static int aq_fw2x_set_state(struct aq_hw_s *self,
enum hal_atl_utils_fw_state_e state);
static u32 aq_fw2x_mbox_get(struct aq_hw_s *self);
static u32 aq_fw2x_rpc_get(struct aq_hw_s *self);
static int aq_fw2x_settings_get(struct aq_hw_s *self, u32 *addr);
static u32 aq_fw2x_state_get(struct aq_hw_s *self);
static u32 aq_fw2x_state2_get(struct aq_hw_s *self);
static int aq_fw2x_init(struct aq_hw_s *self)
{
int err = 0;
/* check 10 times by 1ms */
err = readx_poll_timeout_atomic(aq_fw2x_mbox_get,
self, self->mbox_addr,
self->mbox_addr != 0U,
1000U, 10000U);
err = readx_poll_timeout_atomic(aq_fw2x_rpc_get,
self, self->rpc_addr,
self->rpc_addr != 0U,
1000U, 100000U);
err = aq_fw2x_settings_get(self, &self->settings_addr);
return err;
}
static int aq_fw2x_deinit(struct aq_hw_s *self)
{
int err = aq_fw2x_set_link_speed(self, 0);
if (!err)
err = aq_fw2x_set_state(self, MPI_DEINIT);
return err;
}
static enum hw_atl_fw2x_rate link_speed_mask_2fw2x_ratemask(u32 speed)
{
enum hw_atl_fw2x_rate rate = 0;
if (speed & AQ_NIC_RATE_10G)
rate |= FW2X_RATE_10G;
if (speed & AQ_NIC_RATE_5G)
rate |= FW2X_RATE_5G;
if (speed & AQ_NIC_RATE_2G5)
rate |= FW2X_RATE_2G5;
if (speed & AQ_NIC_RATE_1G)
rate |= FW2X_RATE_1G;
if (speed & AQ_NIC_RATE_100M)
rate |= FW2X_RATE_100M;
return rate;
}
static u32 fw2x_to_eee_mask(u32 speed)
{
u32 rate = 0;
if (speed & HW_ATL_FW2X_CAP_EEE_10G_MASK)
rate |= AQ_NIC_RATE_EEE_10G;
if (speed & HW_ATL_FW2X_CAP_EEE_5G_MASK)
rate |= AQ_NIC_RATE_EEE_5G;
if (speed & HW_ATL_FW2X_CAP_EEE_2G5_MASK)
rate |= AQ_NIC_RATE_EEE_2G5;
if (speed & HW_ATL_FW2X_CAP_EEE_1G_MASK)
rate |= AQ_NIC_RATE_EEE_1G;
return rate;
}
static u32 eee_mask_to_fw2x(u32 speed)
{
u32 rate = 0;
if (speed & AQ_NIC_RATE_EEE_10G)
rate |= HW_ATL_FW2X_CAP_EEE_10G_MASK;
if (speed & AQ_NIC_RATE_EEE_5G)
rate |= HW_ATL_FW2X_CAP_EEE_5G_MASK;
if (speed & AQ_NIC_RATE_EEE_2G5)
rate |= HW_ATL_FW2X_CAP_EEE_2G5_MASK;
if (speed & AQ_NIC_RATE_EEE_1G)
rate |= HW_ATL_FW2X_CAP_EEE_1G_MASK;
return rate;
}
static int aq_fw2x_set_link_speed(struct aq_hw_s *self, u32 speed)
{
u32 val = link_speed_mask_2fw2x_ratemask(speed);
aq_hw_write_reg(self, HW_ATL_FW2X_MPI_CONTROL_ADDR, val);
return 0;
}
static void aq_fw2x_upd_flow_control_bits(struct aq_hw_s *self,
u32 *mpi_state, u32 fc)
{
*mpi_state &= ~(HW_ATL_FW2X_CTRL_PAUSE |
HW_ATL_FW2X_CTRL_ASYMMETRIC_PAUSE);
switch (fc) {
/* There is not explicit mode of RX only pause frames,
* thus, we join this mode with FC full.
* FC full is either Rx, either Tx, or both.
*/
case AQ_NIC_FC_FULL:
case AQ_NIC_FC_RX:
*mpi_state |= HW_ATL_FW2X_CTRL_PAUSE |
HW_ATL_FW2X_CTRL_ASYMMETRIC_PAUSE;
break;
case AQ_NIC_FC_TX:
*mpi_state |= HW_ATL_FW2X_CTRL_ASYMMETRIC_PAUSE;
break;
}
}
static void aq_fw2x_upd_eee_rate_bits(struct aq_hw_s *self, u32 *mpi_opts,
u32 eee_speeds)
{
*mpi_opts &= ~(HW_ATL_FW2X_CAP_EEE_1G_MASK |
HW_ATL_FW2X_CAP_EEE_2G5_MASK |
HW_ATL_FW2X_CAP_EEE_5G_MASK |
HW_ATL_FW2X_CAP_EEE_10G_MASK);
*mpi_opts |= eee_mask_to_fw2x(eee_speeds);
}
static int aq_fw2x_set_state(struct aq_hw_s *self,
enum hal_atl_utils_fw_state_e state)
{
u32 mpi_state = aq_hw_read_reg(self, HW_ATL_FW2X_MPI_CONTROL2_ADDR);
struct aq_nic_cfg_s *cfg = self->aq_nic_cfg;
switch (state) {
case MPI_INIT:
mpi_state &= ~BIT(CAPS_HI_LINK_DROP);
aq_fw2x_upd_eee_rate_bits(self, &mpi_state, cfg->eee_speeds);
aq_fw2x_upd_flow_control_bits(self, &mpi_state,
self->aq_nic_cfg->fc.req);
break;
case MPI_DEINIT:
mpi_state |= BIT(CAPS_HI_LINK_DROP);
break;
case MPI_RESET:
case MPI_POWER:
/* No actions */
break;
}
aq_hw_write_reg(self, HW_ATL_FW2X_MPI_CONTROL2_ADDR, mpi_state);
return 0;
}
static int aq_fw2x_update_link_status(struct aq_hw_s *self)
{
struct aq_hw_link_status_s *link_status = &self->aq_link_status;
u32 mpi_state;
u32 speed;
mpi_state = aq_hw_read_reg(self, HW_ATL_FW2X_MPI_STATE_ADDR);
speed = mpi_state & (FW2X_RATE_100M | FW2X_RATE_1G |
FW2X_RATE_2G5 | FW2X_RATE_5G |
FW2X_RATE_10G);
if (speed) {
if (speed & FW2X_RATE_10G)
link_status->mbps = 10000;
else if (speed & FW2X_RATE_5G)
link_status->mbps = 5000;
else if (speed & FW2X_RATE_2G5)
link_status->mbps = 2500;
else if (speed & FW2X_RATE_1G)
link_status->mbps = 1000;
else if (speed & FW2X_RATE_100M)
link_status->mbps = 100;
else
link_status->mbps = 10000;
} else {
link_status->mbps = 0;
}
link_status->full_duplex = true;
return 0;
}
static int aq_fw2x_get_mac_permanent(struct aq_hw_s *self, u8 *mac)
{
u32 efuse_addr = aq_hw_read_reg(self, HW_ATL_FW2X_MPI_EFUSE_ADDR);
u32 mac_addr[2] = { 0 };
int err = 0;
if (efuse_addr != 0) {
err = hw_atl_utils_fw_downld_dwords(self,
efuse_addr + (40U * 4U),
mac_addr,
ARRAY_SIZE(mac_addr));
if (err)
return err;
mac_addr[0] = __swab32(mac_addr[0]);
mac_addr[1] = __swab32(mac_addr[1]);
}
ether_addr_copy(mac, (u8 *)mac_addr);
return err;
}
static int aq_fw2x_update_stats(struct aq_hw_s *self)
{
u32 mpi_opts = aq_hw_read_reg(self, HW_ATL_FW2X_MPI_CONTROL2_ADDR);
u32 orig_stats_val = mpi_opts & BIT(CAPS_HI_STATISTICS);
u32 stats_val;
int err = 0;
/* Toggle statistics bit for FW to update */
mpi_opts = mpi_opts ^ BIT(CAPS_HI_STATISTICS);
aq_hw_write_reg(self, HW_ATL_FW2X_MPI_CONTROL2_ADDR, mpi_opts);
/* Wait FW to report back */
err = readx_poll_timeout_atomic(aq_fw2x_state2_get,
self, stats_val,
orig_stats_val != (stats_val &
BIT(CAPS_HI_STATISTICS)),
1U, 10000U);
if (err)
return err;
return hw_atl_utils_update_stats(self);
}
static int aq_fw2x_get_phy_temp(struct aq_hw_s *self, int *temp)
{
u32 mpi_opts = aq_hw_read_reg(self, HW_ATL_FW2X_MPI_CONTROL2_ADDR);
u32 temp_val = mpi_opts & HW_ATL_FW2X_CTRL_TEMPERATURE;
u32 phy_temp_offset;
u32 temp_res;
int err = 0;
u32 val;
phy_temp_offset = self->mbox_addr + offsetof(struct hw_atl_utils_mbox,
info.phy_temperature);
/* Toggle statistics bit for FW to 0x36C.18 (CTRL_TEMPERATURE) */
mpi_opts = mpi_opts ^ HW_ATL_FW2X_CTRL_TEMPERATURE;
aq_hw_write_reg(self, HW_ATL_FW2X_MPI_CONTROL2_ADDR, mpi_opts);
/* Wait FW to report back */
err = readx_poll_timeout_atomic(aq_fw2x_state2_get, self, val,
temp_val !=
(val & HW_ATL_FW2X_CTRL_TEMPERATURE),
1U, 10000U);
err = hw_atl_utils_fw_downld_dwords(self, phy_temp_offset,
&temp_res, 1);
if (err)
return err;
/* Convert PHY temperature from 1/256 degree Celsius
* to 1/1000 degree Celsius.
*/
*temp = (int16_t)(temp_res & 0xFFFF) * 1000 / 256;
return 0;
}
static int aq_fw2x_set_wol(struct aq_hw_s *self, const u8 *mac)
{
struct hw_atl_utils_fw_rpc *rpc = NULL;
struct offload_info *info = NULL;
u32 wol_bits = 0;
u32 rpc_size;
int err = 0;
u32 val;
if (self->aq_nic_cfg->wol & WAKE_PHY) {
aq_hw_write_reg(self, HW_ATL_FW2X_MPI_CONTROL2_ADDR,
HW_ATL_FW2X_CTRL_LINK_DROP);
readx_poll_timeout_atomic(aq_fw2x_state2_get, self, val,
(val &
HW_ATL_FW2X_CTRL_LINK_DROP) != 0,
1000, 100000);
wol_bits |= HW_ATL_FW2X_CTRL_WAKE_ON_LINK;
}
if (self->aq_nic_cfg->wol & WAKE_MAGIC) {
wol_bits |= HW_ATL_FW2X_CTRL_SLEEP_PROXY |
HW_ATL_FW2X_CTRL_WOL;
err = hw_atl_utils_fw_rpc_wait(self, &rpc);
if (err < 0)
goto err_exit;
rpc_size = sizeof(*info) +
offsetof(struct hw_atl_utils_fw_rpc, fw2x_offloads);
memset(rpc, 0, rpc_size);
info = &rpc->fw2x_offloads;
memcpy(info->mac_addr, mac, ETH_ALEN);
info->len = sizeof(*info);
err = hw_atl_utils_fw_rpc_call(self, rpc_size);
if (err < 0)
goto err_exit;
}
aq_hw_write_reg(self, HW_ATL_FW2X_MPI_CONTROL2_ADDR, wol_bits);
err_exit:
return err;
}
static int aq_fw2x_set_power(struct aq_hw_s *self, unsigned int power_state,
const u8 *mac)
{
int err = 0;
if (self->aq_nic_cfg->wol)
err = aq_fw2x_set_wol(self, mac);
return err;
}
static int aq_fw2x_send_fw_request(struct aq_hw_s *self,
const struct hw_fw_request_iface *fw_req,
size_t size)
{
u32 ctrl2, orig_ctrl2;
u32 dword_cnt;
int err = 0;
u32 val;
/* Write data to drvIface Mailbox */
dword_cnt = size / sizeof(u32);
if (size % sizeof(u32))
dword_cnt++;
err = hw_atl_write_fwcfg_dwords(self, (void *)fw_req, dword_cnt);
if (err < 0)
goto err_exit;
/* Toggle statistics bit for FW to update */
ctrl2 = aq_hw_read_reg(self, HW_ATL_FW2X_MPI_CONTROL2_ADDR);
orig_ctrl2 = ctrl2 & BIT(CAPS_HI_FW_REQUEST);
ctrl2 = ctrl2 ^ BIT(CAPS_HI_FW_REQUEST);
aq_hw_write_reg(self, HW_ATL_FW2X_MPI_CONTROL2_ADDR, ctrl2);
/* Wait FW to report back */
err = readx_poll_timeout_atomic(aq_fw2x_state2_get, self, val,
orig_ctrl2 != (val &
BIT(CAPS_HI_FW_REQUEST)),
1U, 10000U);
err_exit:
return err;
}
static void aq_fw3x_enable_ptp(struct aq_hw_s *self, int enable)
{
u32 ptp_opts = aq_hw_read_reg(self, HW_ATL_FW3X_EXT_STATE_ADDR);
u32 all_ptp_features = BIT(CAPS_EX_PHY_PTP_EN) |
BIT(CAPS_EX_PTP_GPIO_EN);
if (enable)
ptp_opts |= all_ptp_features;
else
ptp_opts &= ~all_ptp_features;
aq_hw_write_reg(self, HW_ATL_FW3X_EXT_CONTROL_ADDR, ptp_opts);
}
static void aq_fw3x_adjust_ptp(struct aq_hw_s *self, uint64_t adj)
{
aq_hw_write_reg(self, HW_ATL_FW3X_PTP_ADJ_LSW_ADDR,
(adj >> 0) & 0xffffffff);
aq_hw_write_reg(self, HW_ATL_FW3X_PTP_ADJ_MSW_ADDR,
(adj >> 32) & 0xffffffff);
}
static int aq_fw2x_led_control(struct aq_hw_s *self, u32 mode)
{
if (self->fw_ver_actual < HW_ATL_FW_VER_LED)
return -EOPNOTSUPP;
aq_hw_write_reg(self, HW_ATL_FW2X_MPI_LED_ADDR, mode);
return 0;
}
static int aq_fw2x_set_eee_rate(struct aq_hw_s *self, u32 speed)
{
u32 mpi_opts = aq_hw_read_reg(self, HW_ATL_FW2X_MPI_CONTROL2_ADDR);
aq_fw2x_upd_eee_rate_bits(self, &mpi_opts, speed);
aq_hw_write_reg(self, HW_ATL_FW2X_MPI_CONTROL2_ADDR, mpi_opts);
return 0;
}
static int aq_fw2x_get_eee_rate(struct aq_hw_s *self, u32 *rate,
u32 *supported_rates)
{
u32 mpi_state;
u32 caps_hi;
int err = 0;
u32 offset;
offset = self->mbox_addr + offsetof(struct hw_atl_utils_mbox,
info.caps_hi);
err = hw_atl_utils_fw_downld_dwords(self, offset, &caps_hi, 1);
if (err)
return err;
*supported_rates = fw2x_to_eee_mask(caps_hi);
mpi_state = aq_fw2x_state2_get(self);
*rate = fw2x_to_eee_mask(mpi_state);
return err;
}
static int aq_fw2x_renegotiate(struct aq_hw_s *self)
{
u32 mpi_opts = aq_hw_read_reg(self, HW_ATL_FW2X_MPI_CONTROL2_ADDR);
mpi_opts |= BIT(CTRL_FORCE_RECONNECT);
aq_hw_write_reg(self, HW_ATL_FW2X_MPI_CONTROL2_ADDR, mpi_opts);
return 0;
}
static int aq_fw2x_set_flow_control(struct aq_hw_s *self)
{
u32 mpi_state = aq_hw_read_reg(self, HW_ATL_FW2X_MPI_CONTROL2_ADDR);
aq_fw2x_upd_flow_control_bits(self, &mpi_state,
self->aq_nic_cfg->fc.req);
aq_hw_write_reg(self, HW_ATL_FW2X_MPI_CONTROL2_ADDR, mpi_state);
return 0;
}
static u32 aq_fw2x_get_flow_control(struct aq_hw_s *self, u32 *fcmode)
{
u32 mpi_state = aq_fw2x_state2_get(self);
*fcmode = 0;
if (mpi_state & HW_ATL_FW2X_CAP_PAUSE)
*fcmode |= AQ_NIC_FC_RX;
if (mpi_state & HW_ATL_FW2X_CAP_ASYM_PAUSE)
*fcmode |= AQ_NIC_FC_TX;
return 0;
}
static int aq_fw2x_set_phyloopback(struct aq_hw_s *self, u32 mode, bool enable)
{
u32 mpi_opts;
switch (mode) {
case AQ_HW_LOOPBACK_PHYINT_SYS:
mpi_opts = aq_hw_read_reg(self, HW_ATL_FW2X_MPI_CONTROL2_ADDR);
if (enable)
mpi_opts |= HW_ATL_FW2X_CTRL_INT_LOOPBACK;
else
mpi_opts &= ~HW_ATL_FW2X_CTRL_INT_LOOPBACK;
aq_hw_write_reg(self, HW_ATL_FW2X_MPI_CONTROL2_ADDR, mpi_opts);
break;
case AQ_HW_LOOPBACK_PHYEXT_SYS:
mpi_opts = aq_hw_read_reg(self, HW_ATL_FW2X_MPI_CONTROL2_ADDR);
if (enable)
mpi_opts |= HW_ATL_FW2X_CTRL_EXT_LOOPBACK;
else
mpi_opts &= ~HW_ATL_FW2X_CTRL_EXT_LOOPBACK;
aq_hw_write_reg(self, HW_ATL_FW2X_MPI_CONTROL2_ADDR, mpi_opts);
break;
default:
return -EINVAL;
}
return 0;
}
static u32 aq_fw2x_mbox_get(struct aq_hw_s *self)
{
return aq_hw_read_reg(self, HW_ATL_FW2X_MPI_MBOX_ADDR);
}
static u32 aq_fw2x_rpc_get(struct aq_hw_s *self)
{
return aq_hw_read_reg(self, HW_ATL_FW2X_MPI_RPC_ADDR);
}
static int aq_fw2x_settings_get(struct aq_hw_s *self, u32 *addr)
{
int err = 0;
u32 offset;
offset = self->mbox_addr + offsetof(struct hw_atl_utils_mbox,
info.setting_address);
err = hw_atl_utils_fw_downld_dwords(self, offset, addr, 1);
return err;
}
static u32 aq_fw2x_state_get(struct aq_hw_s *self)
{
return aq_hw_read_reg(self, HW_ATL_FW2X_MPI_STATE_ADDR);
}
static u32 aq_fw2x_state2_get(struct aq_hw_s *self)
{
return aq_hw_read_reg(self, HW_ATL_FW2X_MPI_STATE2_ADDR);
}
static int aq_fw2x_set_downshift(struct aq_hw_s *self, u32 counter)
{
int err = 0;
u32 mpi_opts;
u32 offset;
offset = offsetof(struct hw_atl_utils_settings, downshift_retry_count);
err = hw_atl_write_fwsettings_dwords(self, offset, &counter, 1);
if (err)
return err;
mpi_opts = aq_hw_read_reg(self, HW_ATL_FW2X_MPI_CONTROL2_ADDR);
if (counter)
mpi_opts |= HW_ATL_FW2X_CTRL_DOWNSHIFT;
else
mpi_opts &= ~HW_ATL_FW2X_CTRL_DOWNSHIFT;
aq_hw_write_reg(self, HW_ATL_FW2X_MPI_CONTROL2_ADDR, mpi_opts);
return err;
}
static int aq_fw2x_set_media_detect(struct aq_hw_s *self, bool on)
{
u32 enable;
u32 offset;
if (self->fw_ver_actual < HW_ATL_FW_VER_MEDIA_CONTROL)
return -EOPNOTSUPP;
offset = offsetof(struct hw_atl_utils_settings, media_detect);
enable = on;
return hw_atl_write_fwsettings_dwords(self, offset, &enable, 1);
}
static u32 aq_fw2x_get_link_capabilities(struct aq_hw_s *self)
{
int err = 0;
u32 offset;
u32 val;
offset = self->mbox_addr +
offsetof(struct hw_atl_utils_mbox, info.caps_lo);
err = hw_atl_utils_fw_downld_dwords(self, offset, &val, 1);
if (err)
return 0;
return val;
}
static int aq_fw2x_send_macsec_req(struct aq_hw_s *hw,
struct macsec_msg_fw_request *req,
struct macsec_msg_fw_response *response)
{
u32 low_status, low_req = 0;
u32 dword_cnt;
u32 caps_lo;
u32 offset;
int err;
if (!req || !response)
return -EINVAL;
caps_lo = aq_fw2x_get_link_capabilities(hw);
if (!(caps_lo & BIT(CAPS_LO_MACSEC)))
return -EOPNOTSUPP;
/* Write macsec request to cfg memory */
dword_cnt = (sizeof(*req) + sizeof(u32) - 1) / sizeof(u32);
err = hw_atl_write_fwcfg_dwords(hw, (void *)req, dword_cnt);
if (err < 0)
return err;
/* Toggle 0x368.CAPS_LO_MACSEC bit */
low_req = aq_hw_read_reg(hw, HW_ATL_FW2X_MPI_CONTROL_ADDR);
low_req ^= HW_ATL_FW2X_CAP_MACSEC;
aq_hw_write_reg(hw, HW_ATL_FW2X_MPI_CONTROL_ADDR, low_req);
/* Wait FW to report back */
err = readx_poll_timeout_atomic(aq_fw2x_state_get, hw, low_status,
low_req != (low_status & BIT(CAPS_LO_MACSEC)), 1U, 10000U);
if (err)
return -EIO;
/* Read status of write operation */
offset = hw->rpc_addr + sizeof(u32);
err = hw_atl_utils_fw_downld_dwords(hw, offset, (u32 *)(void *)response,
sizeof(*response) / sizeof(u32));
return err;
}
const struct aq_fw_ops aq_fw_2x_ops = {
.init = aq_fw2x_init,
.deinit = aq_fw2x_deinit,
.reset = NULL,
.renegotiate = aq_fw2x_renegotiate,
.get_mac_permanent = aq_fw2x_get_mac_permanent,
.set_link_speed = aq_fw2x_set_link_speed,
.set_state = aq_fw2x_set_state,
.update_link_status = aq_fw2x_update_link_status,
.update_stats = aq_fw2x_update_stats,
.get_mac_temp = NULL,
.get_phy_temp = aq_fw2x_get_phy_temp,
.set_power = aq_fw2x_set_power,
.set_eee_rate = aq_fw2x_set_eee_rate,
.get_eee_rate = aq_fw2x_get_eee_rate,
.set_flow_control = aq_fw2x_set_flow_control,
.get_flow_control = aq_fw2x_get_flow_control,
.send_fw_request = aq_fw2x_send_fw_request,
.enable_ptp = aq_fw3x_enable_ptp,
.led_control = aq_fw2x_led_control,
.set_phyloopback = aq_fw2x_set_phyloopback,
.set_downshift = aq_fw2x_set_downshift,
.set_media_detect = aq_fw2x_set_media_detect,
.adjust_ptp = aq_fw3x_adjust_ptp,
.get_link_capabilities = aq_fw2x_get_link_capabilities,
.send_macsec_req = aq_fw2x_send_macsec_req,
};