/* MCUX Ethernet Driver
*
* Copyright (c) 2016-2017 ARM Ltd
* Copyright (c) 2016 Linaro Ltd
* Copyright (c) 2018 Intel Coporation
*
* SPDX-License-Identifier: Apache-2.0
*/
/* Driver Limitations:
*
* There is no statistics collection for either normal operation or
* error behaviour.
*/
#define LOG_MODULE_NAME eth_mcux
#define LOG_LEVEL CONFIG_ETHERNET_LOG_LEVEL
#include <logging/log.h>
LOG_MODULE_REGISTER(LOG_MODULE_NAME);
#include <device.h>
#include <sys/util.h>
#include <kernel.h>
#include <net/net_pkt.h>
#include <net/net_if.h>
#include <net/ethernet.h>
#include <ethernet/eth_stats.h>
#if defined(CONFIG_PTP_CLOCK_MCUX)
#include <ptp_clock.h>
#include <net/gptp.h>
#endif
#include "fsl_enet.h"
#include "fsl_phy.h"
#define FREESCALE_OUI_B0 0x00
#define FREESCALE_OUI_B1 0x04
#define FREESCALE_OUI_B2 0x9f
enum eth_mcux_phy_state {
eth_mcux_phy_state_initial,
eth_mcux_phy_state_reset,
eth_mcux_phy_state_autoneg,
eth_mcux_phy_state_restart,
eth_mcux_phy_state_read_status,
eth_mcux_phy_state_read_duplex,
eth_mcux_phy_state_wait,
eth_mcux_phy_state_closing
};
static const char *
phy_state_name(enum eth_mcux_phy_state state) __attribute__((unused));
static const char *phy_state_name(enum eth_mcux_phy_state state)
{
static const char * const name[] = {
"initial",
"reset",
"autoneg",
"restart",
"read-status",
"read-duplex",
"wait",
"closing"
};
return name[state];
}
struct eth_context {
/* If VLAN is enabled, there can be multiple VLAN interfaces related to
* this physical device. In that case, this pointer value is not really
* used for anything.
*/
struct net_if *iface;
enet_handle_t enet_handle;
#if defined(CONFIG_PTP_CLOCK_MCUX)
struct device *ptp_clock;
enet_ptp_config_t ptp_config;
float clk_ratio;
#endif
struct k_sem tx_buf_sem;
enum eth_mcux_phy_state phy_state;
bool enabled;
bool link_up;
phy_duplex_t phy_duplex;
phy_speed_t phy_speed;
u8_t mac_addr[6];
struct k_work phy_work;
struct k_delayed_work delayed_phy_work;
/* TODO: FIXME. This Ethernet frame sized buffer is used for
* interfacing with MCUX. How it works is that hardware uses
* DMA scatter buffers to receive a frame, and then public
* MCUX call gathers them into this buffer (there's no other
* public interface). All this happens only for this driver
* to scatter this buffer again into Zephyr fragment buffers.
* This is not efficient, but proper resolution of this issue
* depends on introduction of zero-copy networking support
* in Zephyr, and adding needed interface to MCUX (or
* bypassing it and writing a more complex driver working
* directly with hardware).
*
* Note that we do not copy FCS into this buffer thus the
* size is 1514 bytes.
*/
u8_t frame_buf[NET_ETH_MAX_FRAME_SIZE]; /* Max MTU + ethernet header */
};
static void eth_0_config_func(void);
#ifdef CONFIG_HAS_MCUX_CACHE
static __nocache enet_rx_bd_struct_t __aligned(ENET_BUFF_ALIGNMENT)
rx_buffer_desc[CONFIG_ETH_MCUX_RX_BUFFERS];
static __nocache enet_tx_bd_struct_t __aligned(ENET_BUFF_ALIGNMENT)
tx_buffer_desc[CONFIG_ETH_MCUX_TX_BUFFERS];
#else
static enet_rx_bd_struct_t __aligned(ENET_BUFF_ALIGNMENT)
rx_buffer_desc[CONFIG_ETH_MCUX_RX_BUFFERS];
static enet_tx_bd_struct_t __aligned(ENET_BUFF_ALIGNMENT)
tx_buffer_desc[CONFIG_ETH_MCUX_TX_BUFFERS];
#endif
#if defined(CONFIG_PTP_CLOCK_MCUX)
/* Packets to be timestamped. */
static struct net_pkt *ts_tx_pkt[CONFIG_ETH_MCUX_TX_BUFFERS];
static int ts_tx_rd, ts_tx_wr;
#endif
/* Use ENET_FRAME_MAX_VALNFRAMELEN for VLAN frame size
* Use ENET_FRAME_MAX_FRAMELEN for ethernet frame size
*/
#if defined(CONFIG_NET_VLAN)
#if !defined(ENET_FRAME_MAX_VALNFRAMELEN)
#define ENET_FRAME_MAX_VALNFRAMELEN (ENET_FRAME_MAX_FRAMELEN + 4)
#endif
#define ETH_MCUX_BUFFER_SIZE \
ROUND_UP(ENET_FRAME_MAX_VALNFRAMELEN, ENET_BUFF_ALIGNMENT)
#else
#define ETH_MCUX_BUFFER_SIZE \
ROUND_UP(ENET_FRAME_MAX_FRAMELEN, ENET_BUFF_ALIGNMENT)
#endif /* CONFIG_NET_VLAN */
static u8_t __aligned(ENET_BUFF_ALIGNMENT)
rx_buffer[CONFIG_ETH_MCUX_RX_BUFFERS][ETH_MCUX_BUFFER_SIZE];
static u8_t __aligned(ENET_BUFF_ALIGNMENT)
tx_buffer[CONFIG_ETH_MCUX_TX_BUFFERS][ETH_MCUX_BUFFER_SIZE];
static void eth_mcux_decode_duplex_and_speed(u32_t status,
phy_duplex_t *p_phy_duplex,
phy_speed_t *p_phy_speed)
{
switch (status & PHY_CTL1_SPEEDUPLX_MASK) {
case PHY_CTL1_10FULLDUPLEX_MASK:
*p_phy_duplex = kPHY_FullDuplex;
*p_phy_speed = kPHY_Speed10M;
break;
case PHY_CTL1_100FULLDUPLEX_MASK:
*p_phy_duplex = kPHY_FullDuplex;
*p_phy_speed = kPHY_Speed100M;
break;
case PHY_CTL1_100HALFDUPLEX_MASK:
*p_phy_duplex = kPHY_HalfDuplex;
*p_phy_speed = kPHY_Speed100M;
break;
case PHY_CTL1_10HALFDUPLEX_MASK:
*p_phy_duplex = kPHY_HalfDuplex;
*p_phy_speed = kPHY_Speed10M;
break;
}
}
static inline struct net_if *get_iface(struct eth_context *ctx, u16_t vlan_tag)
{
#if defined(CONFIG_NET_VLAN)
struct net_if *iface;
iface = net_eth_get_vlan_iface(ctx->iface, vlan_tag);
if (!iface) {
return ctx->iface;
}
return iface;
#else
ARG_UNUSED(vlan_tag);
return ctx->iface;
#endif
}
static void eth_mcux_phy_enter_reset(struct eth_context *context)
{
const u32_t phy_addr = 0U;
/* Reset the PHY. */
ENET_StartSMIWrite(ENET, phy_addr, PHY_BASICCONTROL_REG,
kENET_MiiWriteValidFrame,
PHY_BCTL_RESET_MASK);
context->phy_state = eth_mcux_phy_state_reset;
}
static void eth_mcux_phy_start(struct eth_context *context)
{
const u32_t phy_addr = 0U;
#ifdef CONFIG_ETH_MCUX_PHY_EXTRA_DEBUG
LOG_DBG("phy_state=%s", phy_state_name(context->phy_state));
#endif
context->enabled = true;
switch (context->phy_state) {
case eth_mcux_phy_state_initial:
ENET_ActiveRead(ENET);
/* Reset the PHY. */
ENET_StartSMIWrite(ENET, phy_addr, PHY_BASICCONTROL_REG,
kENET_MiiWriteValidFrame,
PHY_BCTL_RESET_MASK);
#ifdef CONFIG_SOC_SERIES_IMX_RT
context->phy_state = eth_mcux_phy_state_initial;
#else
context->phy_state = eth_mcux_phy_state_reset;
#endif
break;
case eth_mcux_phy_state_reset:
eth_mcux_phy_enter_reset(context);
break;
case eth_mcux_phy_state_autoneg:
case eth_mcux_phy_state_restart:
case eth_mcux_phy_state_read_status:
case eth_mcux_phy_state_read_duplex:
case eth_mcux_phy_state_wait:
case eth_mcux_phy_state_closing:
break;
}
}
void eth_mcux_phy_stop(struct eth_context *context)
{
#ifdef CONFIG_ETH_MCUX_PHY_EXTRA_DEBUG
LOG_DBG("phy_state=%s", phy_state_name(context->phy_state));
#endif
context->enabled = false;
switch (context->phy_state) {
case eth_mcux_phy_state_initial:
case eth_mcux_phy_state_reset:
case eth_mcux_phy_state_autoneg:
case eth_mcux_phy_state_restart:
case eth_mcux_phy_state_read_status:
case eth_mcux_phy_state_read_duplex:
/* Do nothing, let the current communication complete
* then deal with shutdown.
*/
context->phy_state = eth_mcux_phy_state_closing;
break;
case eth_mcux_phy_state_wait:
k_delayed_work_cancel(&context->delayed_phy_work);
/* @todo, actually power downt he PHY ? */
context->phy_state = eth_mcux_phy_state_initial;
break;
case eth_mcux_phy_state_closing:
/* We are already going down. */
break;
}
}
static void eth_mcux_phy_event(struct eth_context *context)
{
u32_t status;
bool link_up;
phy_duplex_t phy_duplex = kPHY_FullDuplex;
phy_speed_t phy_speed = kPHY_Speed100M;
const u32_t phy_addr = 0U;
#ifdef CONFIG_ETH_MCUX_PHY_EXTRA_DEBUG
LOG_DBG("phy_state=%s", phy_state_name(context->phy_state));
#endif
switch (context->phy_state) {
case eth_mcux_phy_state_initial:
#ifdef CONFIG_SOC_SERIES_IMX_RT
ENET_StartSMIRead(ENET, phy_addr, PHY_CONTROL2_REG,
kENET_MiiReadValidFrame);
ENET_StartSMIWrite(ENET, phy_addr, PHY_CONTROL2_REG,
kENET_MiiWriteValidFrame, PHY_CTL2_REFCLK_SELECT_MASK);
context->phy_state = eth_mcux_phy_state_reset;
#endif
break;
case eth_mcux_phy_state_closing:
if (context->enabled) {
eth_mcux_phy_enter_reset(context);
} else {
/* @todo, actually power down the PHY ? */
context->phy_state = eth_mcux_phy_state_initial;
}
break;
case eth_mcux_phy_state_reset:
/* Setup PHY autonegotiation. */
ENET_StartSMIWrite(ENET, phy_addr, PHY_AUTONEG_ADVERTISE_REG,
kENET_MiiWriteValidFrame,
(PHY_100BASETX_FULLDUPLEX_MASK |
PHY_100BASETX_HALFDUPLEX_MASK |
PHY_10BASETX_FULLDUPLEX_MASK |
PHY_10BASETX_HALFDUPLEX_MASK | 0x1U));
context->phy_state = eth_mcux_phy_state_autoneg;
break;
case eth_mcux_phy_state_autoneg:
/* Setup PHY autonegotiation. */
ENET_StartSMIWrite(ENET, phy_addr, PHY_BASICCONTROL_REG,
kENET_MiiWriteValidFrame,
(PHY_BCTL_AUTONEG_MASK |
PHY_BCTL_RESTART_AUTONEG_MASK));
context->phy_state = eth_mcux_phy_state_restart;
break;
case eth_mcux_phy_state_wait:
case eth_mcux_phy_state_restart:
/* Start reading the PHY basic status. */
ENET_StartSMIRead(ENET, phy_addr, PHY_BASICSTATUS_REG,
kENET_MiiReadValidFrame);
context->phy_state = eth_mcux_phy_state_read_status;
break;
case eth_mcux_phy_state_read_status:
/* PHY Basic status is available. */
status = ENET_ReadSMIData(ENET);
link_up = status & PHY_BSTATUS_LINKSTATUS_MASK;
if (link_up && !context->link_up) {
/* Start reading the PHY control register. */
ENET_StartSMIRead(ENET, phy_addr, PHY_CONTROL1_REG,
kENET_MiiReadValidFrame);
context->link_up = link_up;
context->phy_state = eth_mcux_phy_state_read_duplex;
/* Network interface might be NULL at this point */
if (context->iface) {
net_eth_carrier_on(context->iface);
k_sleep(USEC_PER_MSEC);
}
} else if (!link_up && context->link_up) {
LOG_INF("Link down");
context->link_up = link_up;
k_delayed_work_submit(&context->delayed_phy_work,
CONFIG_ETH_MCUX_PHY_TICK_MS);
context->phy_state = eth_mcux_phy_state_wait;
net_eth_carrier_off(context->iface);
} else {
k_delayed_work_submit(&context->delayed_phy_work,
CONFIG_ETH_MCUX_PHY_TICK_MS);
context->phy_state = eth_mcux_phy_state_wait;
}
break;
case eth_mcux_phy_state_read_duplex:
/* PHY control register is available. */
status = ENET_ReadSMIData(ENET);
eth_mcux_decode_duplex_and_speed(status,
&phy_duplex,
&phy_speed);
if (phy_speed != context->phy_speed ||
phy_duplex != context->phy_duplex) {
context->phy_speed = phy_speed;
context->phy_duplex = phy_duplex;
ENET_SetMII(ENET,
(enet_mii_speed_t) phy_speed,
(enet_mii_duplex_t) phy_duplex);
}
LOG_INF("Enabled %sM %s-duplex mode.",
(phy_speed ? "100" : "10"),
(phy_duplex ? "full" : "half"));
k_delayed_work_submit(&context->delayed_phy_work,
CONFIG_ETH_MCUX_PHY_TICK_MS);
context->phy_state = eth_mcux_phy_state_wait;
break;
}
}
static void eth_mcux_phy_work(struct k_work *item)
{
struct eth_context *context =
CONTAINER_OF(item, struct eth_context, phy_work);
eth_mcux_phy_event(context);
}
static void eth_mcux_delayed_phy_work(struct k_work *item)
{
struct eth_context *context =
CONTAINER_OF(item, struct eth_context, delayed_phy_work);
eth_mcux_phy_event(context);
}
static void eth_mcux_phy_setup(void)
{
#ifdef CONFIG_SOC_SERIES_IMX_RT
const u32_t phy_addr = 0U;
status_t res;
u32_t oms_override;
/* Disable MII interrupts to prevent triggering PHY events. */
ENET_DisableInterrupts(ENET, ENET_EIR_MII_MASK);
/* Prevent PHY entering NAND Tree mode override. */
res = PHY_Read(ENET, phy_addr, PHY_OMS_OVERRIDE_REG, &oms_override);
if (res != kStatus_Success) {
LOG_WRN("Reading PHY reg failed (status 0x%x)", res);
} else {
if (oms_override & PHY_OMS_NANDTREE_MASK) {
oms_override &= ~PHY_OMS_NANDTREE_MASK;
res = PHY_Write(ENET, phy_addr, PHY_OMS_OVERRIDE_REG,
oms_override);
if (res != kStatus_Success) {
LOG_WRN("Writing PHY reg failed (status 0x%x)",
res);
}
}
}
ENET_EnableInterrupts(ENET, ENET_EIR_MII_MASK);
#endif
}
#if defined(CONFIG_PTP_CLOCK_MCUX)
static enet_ptp_time_data_t ptp_rx_buffer[CONFIG_ETH_MCUX_PTP_RX_BUFFERS];
static enet_ptp_time_data_t ptp_tx_buffer[CONFIG_ETH_MCUX_PTP_TX_BUFFERS];
static bool eth_get_ptp_data(struct net_if *iface, struct net_pkt *pkt,
enet_ptp_time_data_t *ptpTsData, bool is_tx)
{
int eth_hlen;
#if defined(CONFIG_NET_VLAN)
struct net_eth_vlan_hdr *hdr_vlan;
struct ethernet_context *eth_ctx;
bool vlan_enabled = false;
eth_ctx = net_if_l2_data(iface);
if (net_eth_is_vlan_enabled(eth_ctx, iface)) {
hdr_vlan = (struct net_eth_vlan_hdr *)NET_ETH_HDR(pkt);
vlan_enabled = true;
if (ntohs(hdr_vlan->type) != NET_ETH_PTYPE_PTP) {
return false;
}
eth_hlen = sizeof(struct net_eth_vlan_hdr);
} else
#endif
{
if (ntohs(NET_ETH_HDR(pkt)->type) != NET_ETH_PTYPE_PTP) {
return false;
}
eth_hlen = sizeof(struct net_eth_hdr);
}
net_pkt_set_priority(pkt, NET_PRIORITY_CA);
if (ptpTsData) {
/* Cannot use GPTP_HDR as net_pkt fields are not all filled */
struct gptp_hdr *hdr;
/* In TX, the first net_buf contains the Ethernet header
* and the actual gPTP header is in the second net_buf.
* In RX, the Ethernet header + other headers are in the
* first net_buf.
*/
if (is_tx) {
if (pkt->frags->frags == NULL) {
return false;
}
hdr = (struct gptp_hdr *)pkt->frags->frags->data;
} else {
hdr = (struct gptp_hdr *)(pkt->frags->data +
eth_hlen);
}
ptpTsData->version = hdr->ptp_version;
memcpy(ptpTsData->sourcePortId, &hdr->port_id,
kENET_PtpSrcPortIdLen);
ptpTsData->messageType = hdr->message_type;
ptpTsData->sequenceId = ntohs(hdr->sequence_id);
#ifdef CONFIG_ETH_MCUX_PHY_EXTRA_DEBUG
LOG_DBG("PTP packet: ver %d type %d len %d seq %d",
ptpTsData->version,
ptpTsData->messageType,
ntohs(hdr->message_length),
ptpTsData->sequenceId);
LOG_DBG(" clk %02x%02x%02x%02x%02x%02x%02x%02x port %d",
hdr->port_id.clk_id[0],
hdr->port_id.clk_id[1],
hdr->port_id.clk_id[2],
hdr->port_id.clk_id[3],
hdr->port_id.clk_id[4],
hdr->port_id.clk_id[5],
hdr->port_id.clk_id[6],
hdr->port_id.clk_id[7],
ntohs(hdr->port_id.port_number));
#endif
}
return true;
}
#endif /* CONFIG_PTP_CLOCK_MCUX */
static int eth_tx(struct device *dev, struct net_pkt *pkt)
{
struct eth_context *context = dev->driver_data;
u16_t total_len = net_pkt_get_len(pkt);
status_t status;
unsigned int imask;
#if defined(CONFIG_PTP_CLOCK_MCUX)
bool timestamped_frame;
#endif
/* As context->frame_buf is shared resource used by both eth_tx
* and eth_rx, we need to protect it with irq_lock.
*/
imask = irq_lock();
if (net_pkt_read(pkt, context->frame_buf, total_len)) {
irq_unlock(imask);
return -EIO;
}
/* FIXME: Dirty workaround.
* With current implementation of ENET_StoreTxFrameTime in the MCUX
* library, a frame may not be timestamped when a non-timestamped frame
* is sent.
*/
#ifdef ENET_ENHANCEDBUFFERDESCRIPTOR_MODE
context->enet_handle.txBdDirtyTime[0] =
context->enet_handle.txBdCurrent[0];
#endif
status = ENET_SendFrame(ENET, &context->enet_handle, context->frame_buf,
total_len);
#if defined(CONFIG_PTP_CLOCK_MCUX)
timestamped_frame = eth_get_ptp_data(net_pkt_iface(pkt), pkt, NULL,
true);
if (timestamped_frame) {
if (!status) {
ts_tx_pkt[ts_tx_wr] = net_pkt_ref(pkt);
} else {
ts_tx_pkt[ts_tx_wr] = NULL;
}
ts_tx_wr++;
if (ts_tx_wr >= CONFIG_ETH_MCUX_TX_BUFFERS) {
ts_tx_wr = 0;
}
}
#endif
irq_unlock(imask);
if (status) {
LOG_ERR("ENET_SendFrame error: %d", (int)status);
return -1;
}
k_sem_take(&context->tx_buf_sem, K_FOREVER);
return 0;
}
static void eth_rx(struct device *iface)
{
struct eth_context *context = iface->driver_data;
u16_t vlan_tag = NET_VLAN_TAG_UNSPEC;
u32_t frame_length = 0U;
struct net_pkt *pkt;
status_t status;
unsigned int imask;
#if defined(CONFIG_PTP_CLOCK_MCUX)
enet_ptp_time_data_t ptpTimeData;
#endif
status = ENET_GetRxFrameSize(&context->enet_handle,
(uint32_t *)&frame_length);
if (status) {
enet_data_error_stats_t error_stats;
LOG_ERR("ENET_GetRxFrameSize return: %d", (int)status);
ENET_GetRxErrBeforeReadFrame(&context->enet_handle,
&error_stats);
goto flush;
}
if (sizeof(context->frame_buf) < frame_length) {
LOG_ERR("frame too large (%d)", frame_length);
goto flush;
}
/* Using root iface. It will be updated in net_recv_data() */
pkt = net_pkt_rx_alloc_with_buffer(context->iface, frame_length,
AF_UNSPEC, 0, K_NO_WAIT);
if (!pkt) {
goto flush;
}
/* As context->frame_buf is shared resource used by both eth_tx
* and eth_rx, we need to protect it with irq_lock.
*/
imask = irq_lock();
status = ENET_ReadFrame(ENET, &context->enet_handle,
context->frame_buf, frame_length);
if (status) {
irq_unlock(imask);
LOG_ERR("ENET_ReadFrame failed: %d", (int)status);
net_pkt_unref(pkt);
goto error;
}
if (net_pkt_write(pkt, context->frame_buf, frame_length)) {
irq_unlock(imask);
LOG_ERR("Unable to write frame into the pkt");
net_pkt_unref(pkt);
goto error;
}
#if defined(CONFIG_NET_VLAN)
{
struct net_eth_hdr *hdr = NET_ETH_HDR(pkt);
if (ntohs(hdr->type) == NET_ETH_PTYPE_VLAN) {
struct net_eth_vlan_hdr *hdr_vlan =
(struct net_eth_vlan_hdr *)NET_ETH_HDR(pkt);
net_pkt_set_vlan_tci(pkt, ntohs(hdr_vlan->vlan.tci));
vlan_tag = net_pkt_vlan_tag(pkt);
#if CONFIG_NET_TC_RX_COUNT > 1
{
enum net_priority prio;
prio = net_vlan2priority(
net_pkt_vlan_priority(pkt));
net_pkt_set_priority(pkt, prio);
}
#endif
}
}
#endif
#if defined(CONFIG_PTP_CLOCK_MCUX)
if (eth_get_ptp_data(get_iface(context, vlan_tag), pkt,
&ptpTimeData, false) &&
(ENET_GetRxFrameTime(&context->enet_handle,
&ptpTimeData) == kStatus_Success)) {
pkt->timestamp.nanosecond = ptpTimeData.timeStamp.nanosecond;
pkt->timestamp.second = ptpTimeData.timeStamp.second;
} else {
/* Invalid value. */
pkt->timestamp.nanosecond = UINT32_MAX;
pkt->timestamp.second = UINT64_MAX;
}
#endif /* CONFIG_PTP_CLOCK_MCUX */
irq_unlock(imask);
if (net_recv_data(get_iface(context, vlan_tag), pkt) < 0) {
net_pkt_unref(pkt);
goto error;
}
return;
flush:
/* Flush the current read buffer. This operation can
* only report failure if there is no frame to flush,
* which cannot happen in this context.
*/
status = ENET_ReadFrame(ENET, &context->enet_handle, NULL, 0);
assert(status == kStatus_Success);
error:
eth_stats_update_errors_rx(get_iface(context, vlan_tag));
}
#if defined(CONFIG_PTP_CLOCK_MCUX)
static inline void ts_register_tx_event(struct eth_context *context)
{
struct net_pkt *pkt;
enet_ptp_time_data_t timeData;
pkt = ts_tx_pkt[ts_tx_rd];
if (pkt && atomic_get(&pkt->atomic_ref) > 0) {
if (eth_get_ptp_data(net_pkt_iface(pkt), pkt, &timeData,
true)) {
int status;
status = ENET_GetTxFrameTime(&context->enet_handle,
&timeData);
if (status == kStatus_Success) {
pkt->timestamp.nanosecond =
timeData.timeStamp.nanosecond;
pkt->timestamp.second =
timeData.timeStamp.second;
net_if_add_tx_timestamp(pkt);
}
}
net_pkt_unref(pkt);
} else {
if (IS_ENABLED(CONFIG_ETH_MCUX_PHY_EXTRA_DEBUG) && pkt) {
LOG_ERR("pkt %p already freed", pkt);
}
}
ts_tx_pkt[ts_tx_rd++] = NULL;
if (ts_tx_rd >= CONFIG_ETH_MCUX_TX_BUFFERS) {
ts_tx_rd = 0;
}
}
#endif
static void eth_callback(ENET_Type *base, enet_handle_t *handle,
enet_event_t event, void *param)
{
struct device *iface = param;
struct eth_context *context = iface->driver_data;
switch (event) {
case kENET_RxEvent:
eth_rx(iface);
break;
case kENET_TxEvent:
#if defined(CONFIG_PTP_CLOCK_MCUX)
/* Register event */
ts_register_tx_event(context);
#endif /* CONFIG_PTP_CLOCK_MCUX */
/* Free the TX buffer. */
k_sem_give(&context->tx_buf_sem);
break;
case kENET_ErrEvent:
/* Error event: BABR/BABT/EBERR/LC/RL/UN/PLR. */
break;
case kENET_WakeUpEvent:
/* Wake up from sleep mode event. */
break;
case kENET_TimeStampEvent:
/* Time stamp event. */
/* Reset periodic timer to default value. */
ENET->ATPER = NSEC_PER_SEC;
break;
case kENET_TimeStampAvailEvent:
/* Time stamp available event. */
break;
}
}
#if defined(CONFIG_ETH_MCUX_0_RANDOM_MAC)
static void generate_mac(u8_t *mac_addr)
{
u32_t entropy;
entropy = sys_rand32_get();
mac_addr[0] |= 0x02; /* force LAA bit */
mac_addr[3] = entropy >> 8;
mac_addr[4] = entropy >> 16;
mac_addr[5] = entropy >> 0;
}
#elif defined(CONFIG_ETH_MCUX_0_UNIQUE_MAC)
static void generate_mac(u8_t *mac_addr)
{
/* Trivially "hash" up to 128 bits of MCU unique identifier */
#ifdef CONFIG_SOC_SERIES_IMX_RT
u32_t id = OCOTP->CFG1 ^ OCOTP->CFG2;
#endif
#ifdef CONFIG_SOC_SERIES_KINETIS_K6X
u32_t id = SIM->UIDH ^ SIM->UIDMH ^ SIM->UIDML ^ SIM->UIDL;
#endif
mac_addr[0] |= 0x02; /* force LAA bit */
mac_addr[3] = id >> 8;
mac_addr[4] = id >> 16;
mac_addr[5] = id >> 0;
}
#endif
static int eth_0_init(struct device *dev)
{
struct eth_context *context = dev->driver_data;
enet_config_t enet_config;
u32_t sys_clock;
enet_buffer_config_t buffer_config = {
.rxBdNumber = CONFIG_ETH_MCUX_RX_BUFFERS,
.txBdNumber = CONFIG_ETH_MCUX_TX_BUFFERS,
.rxBuffSizeAlign = ETH_MCUX_BUFFER_SIZE,
.txBuffSizeAlign = ETH_MCUX_BUFFER_SIZE,
.rxBdStartAddrAlign = rx_buffer_desc,
.txBdStartAddrAlign = tx_buffer_desc,
.rxBufferAlign = rx_buffer[0],
.txBufferAlign = tx_buffer[0],
};
#if defined(CONFIG_PTP_CLOCK_MCUX)
u8_t ptp_multicast[6] = { 0x01, 0x80, 0xC2, 0x00, 0x00, 0x0E };
#endif
#if defined(CONFIG_MDNS_RESPONDER) || defined(CONFIG_MDNS_RESOLVER)
/* standard multicast MAC address */
u8_t mdns_multicast[6] = { 0x01, 0x00, 0x5E, 0x00, 0x00, 0xFB };
#endif
#if defined(CONFIG_PTP_CLOCK_MCUX)
ts_tx_rd = 0;
ts_tx_wr = 0;
(void)memset(ts_tx_pkt, 0, sizeof(ts_tx_pkt));
#endif
k_sem_init(&context->tx_buf_sem,
0, CONFIG_ETH_MCUX_TX_BUFFERS);
k_work_init(&context->phy_work, eth_mcux_phy_work);
k_delayed_work_init(&context->delayed_phy_work,
eth_mcux_delayed_phy_work);
sys_clock = CLOCK_GetFreq(kCLOCK_CoreSysClk);
ENET_GetDefaultConfig(&enet_config);
enet_config.interrupt |= kENET_RxFrameInterrupt;
enet_config.interrupt |= kENET_TxFrameInterrupt;
enet_config.interrupt |= kENET_MiiInterrupt;
#ifdef CONFIG_ETH_MCUX_PROMISCUOUS_MODE
enet_config.macSpecialConfig |= kENET_ControlPromiscuousEnable;
#endif
/* Initialize/override OUI which may not be correct in
* devicetree.
*/
context->mac_addr[0] = FREESCALE_OUI_B0;
context->mac_addr[1] = FREESCALE_OUI_B1;
context->mac_addr[2] = FREESCALE_OUI_B2;
#if defined(CONFIG_ETH_MCUX_0_UNIQUE_MAC) || \
defined(CONFIG_ETH_MCUX_0_RANDOM_MAC)
generate_mac(context->mac_addr);
#endif
#if defined(CONFIG_NET_VLAN)
enet_config.macSpecialConfig |= kENET_ControlVLANTagEnable;
#endif
#if defined(CONFIG_ETH_MCUX_HW_ACCELERATION)
enet_config.txAccelerConfig |=
kENET_TxAccelIpCheckEnabled | kENET_TxAccelProtoCheckEnabled;
enet_config.rxAccelerConfig |=
kENET_RxAccelIpCheckEnabled | kENET_RxAccelProtoCheckEnabled;
#endif
ENET_Init(ENET,
&context->enet_handle,
&enet_config,
&buffer_config,
context->mac_addr,
sys_clock);
#if defined(CONFIG_PTP_CLOCK_MCUX)
ENET_AddMulticastGroup(ENET, ptp_multicast);
context->ptp_config.ptpTsRxBuffNum = CONFIG_ETH_MCUX_PTP_RX_BUFFERS;
context->ptp_config.ptpTsTxBuffNum = CONFIG_ETH_MCUX_PTP_TX_BUFFERS;
context->ptp_config.rxPtpTsData = ptp_rx_buffer;
context->ptp_config.txPtpTsData = ptp_tx_buffer;
context->ptp_config.channel = kENET_PtpTimerChannel1;
context->ptp_config.ptp1588ClockSrc_Hz =
CONFIG_ETH_MCUX_PTP_CLOCK_SRC_HZ;
context->clk_ratio = 1.0;
ENET_Ptp1588Configure(ENET, &context->enet_handle,
&context->ptp_config);
#endif
#if defined(CONFIG_MDNS_RESPONDER) || defined(CONFIG_MDNS_RESOLVER)
ENET_AddMulticastGroup(ENET, mdns_multicast);
#endif
ENET_SetSMI(ENET, sys_clock, false);
/* handle PHY setup after SMI initialization */
eth_mcux_phy_setup();
LOG_DBG("MAC %02x:%02x:%02x:%02x:%02x:%02x",
context->mac_addr[0], context->mac_addr[1],
context->mac_addr[2], context->mac_addr[3],
context->mac_addr[4], context->mac_addr[5]);
ENET_SetCallback(&context->enet_handle, eth_callback, dev);
eth_mcux_phy_start(context);
return 0;
}
#if defined(CONFIG_NET_IPV6)
static void net_if_mcast_cb(struct net_if *iface,
const struct in6_addr *addr,
bool is_joined)
{
struct net_eth_addr mac_addr;
net_eth_ipv6_mcast_to_mac_addr(addr, &mac_addr);
if (is_joined) {
ENET_AddMulticastGroup(ENET, mac_addr.addr);
} else {
ENET_LeaveMulticastGroup(ENET, mac_addr.addr);
}
}
#endif /* CONFIG_NET_IPV6 */
static void eth_iface_init(struct net_if *iface)
{
struct device *dev = net_if_get_device(iface);
struct eth_context *context = dev->driver_data;
#if defined(CONFIG_NET_IPV6)
static struct net_if_mcast_monitor mon;
net_if_mcast_mon_register(&mon, iface, net_if_mcast_cb);
#endif /* CONFIG_NET_IPV6 */
net_if_set_link_addr(iface, context->mac_addr,
sizeof(context->mac_addr),
NET_LINK_ETHERNET);
/* For VLAN, this value is only used to get the correct L2 driver.
* The iface pointer in context should contain the main interface
* if the VLANs are enabled.
*/
if (context->iface == NULL) {
context->iface = iface;
}
ethernet_init(iface);
net_if_flag_set(iface, NET_IF_NO_AUTO_START);
eth_0_config_func();
}
static enum ethernet_hw_caps eth_mcux_get_capabilities(struct device *dev)
{
ARG_UNUSED(dev);
return ETHERNET_HW_VLAN | ETHERNET_LINK_10BASE_T |
#if defined(CONFIG_PTP_CLOCK_MCUX)
ETHERNET_PTP |
#endif
#if defined(CONFIG_ETH_MCUX_HW_ACCELERATION)
ETHERNET_HW_TX_CHKSUM_OFFLOAD |
ETHERNET_HW_RX_CHKSUM_OFFLOAD |
#endif
ETHERNET_AUTO_NEGOTIATION_SET |
ETHERNET_LINK_100BASE_T;
}
#if defined(CONFIG_PTP_CLOCK_MCUX)
static struct device *eth_mcux_get_ptp_clock(struct device *dev)
{
struct eth_context *context = dev->driver_data;
return context->ptp_clock;
}
#endif
static const struct ethernet_api api_funcs = {
.iface_api.init = eth_iface_init,
#if defined(CONFIG_PTP_CLOCK_MCUX)
.get_ptp_clock = eth_mcux_get_ptp_clock,
#endif
.get_capabilities = eth_mcux_get_capabilities,
.send = eth_tx,
};
#if defined(CONFIG_PTP_CLOCK_MCUX)
static void eth_mcux_ptp_isr(void *p)
{
struct device *dev = p;
struct eth_context *context = dev->driver_data;
ENET_Ptp1588TimerIRQHandler(ENET, &context->enet_handle);
}
#endif
#if defined(DT_IRQ_ETH_COMMON)
static void eth_mcux_dispacher_isr(void *p)
{
struct device *dev = p;
struct eth_context *context = dev->driver_data;
u32_t EIR = ENET_GetInterruptStatus(ENET);
int irq_lock_key = irq_lock();
if (EIR & (kENET_RxBufferInterrupt | kENET_RxFrameInterrupt)) {
ENET_ReceiveIRQHandler(ENET, &context->enet_handle);
} else if (EIR & (kENET_TxBufferInterrupt | kENET_TxFrameInterrupt)) {
ENET_TransmitIRQHandler(ENET, &context->enet_handle);
} else if (EIR & ENET_EIR_MII_MASK) {
k_work_submit(&context->phy_work);
ENET_ClearInterruptStatus(ENET, kENET_MiiInterrupt);
} else if (EIR) {
ENET_ClearInterruptStatus(ENET, 0xFFFFFFFF);
}
irq_unlock(irq_lock_key);
}
#endif
#if defined(DT_IRQ_ETH_RX)
static void eth_mcux_rx_isr(void *p)
{
struct device *dev = p;
struct eth_context *context = dev->driver_data;
ENET_ReceiveIRQHandler(ENET, &context->enet_handle);
}
#endif
#if defined(DT_IRQ_ETH_TX)
static void eth_mcux_tx_isr(void *p)
{
struct device *dev = p;
struct eth_context *context = dev->driver_data;
ENET_TransmitIRQHandler(ENET, &context->enet_handle);
}
#endif
#if defined(DT_IRQ_ETH_ERR_MISC)
static void eth_mcux_error_isr(void *p)
{
struct device *dev = p;
struct eth_context *context = dev->driver_data;
u32_t pending = ENET_GetInterruptStatus(ENET);
if (pending & ENET_EIR_MII_MASK) {
k_work_submit(&context->phy_work);
ENET_ClearInterruptStatus(ENET, kENET_MiiInterrupt);
}
}
#endif
static struct eth_context eth_0_context = {
.phy_duplex = kPHY_FullDuplex,
.phy_speed = kPHY_Speed100M,
#if defined(CONFIG_ETH_MCUX_0_MANUAL_MAC)
.mac_addr = DT_ETH_MCUX_0_MAC,
#endif
};
ETH_NET_DEVICE_INIT(eth_mcux_0, DT_ETH_MCUX_0_NAME, eth_0_init,
ð_0_context, NULL, CONFIG_ETH_INIT_PRIORITY,
&api_funcs, NET_ETH_MTU);
static void eth_0_config_func(void)
{
#if defined(DT_IRQ_ETH_RX)
IRQ_CONNECT(DT_IRQ_ETH_RX, DT_ETH_MCUX_0_IRQ_PRI,
eth_mcux_rx_isr, DEVICE_GET(eth_mcux_0), 0);
irq_enable(DT_IRQ_ETH_RX);
#endif
#if defined(DT_IRQ_ETH_TX)
IRQ_CONNECT(DT_IRQ_ETH_TX, DT_ETH_MCUX_0_IRQ_PRI,
eth_mcux_tx_isr, DEVICE_GET(eth_mcux_0), 0);
irq_enable(DT_IRQ_ETH_TX);
#endif
#if defined(DT_IRQ_ETH_ERR_MISC)
IRQ_CONNECT(DT_IRQ_ETH_ERR_MISC, DT_ETH_MCUX_0_IRQ_PRI,
eth_mcux_error_isr, DEVICE_GET(eth_mcux_0), 0);
irq_enable(DT_IRQ_ETH_ERR_MISC);
#endif
#if defined(DT_IRQ_ETH_COMMON)
IRQ_CONNECT(DT_IRQ_ETH_COMMON, DT_ETH_MCUX_0_IRQ_PRI,
eth_mcux_dispacher_isr, DEVICE_GET(eth_mcux_0), 0);
irq_enable(DT_IRQ_ETH_COMMON);
#endif
#if defined(CONFIG_PTP_CLOCK_MCUX)
IRQ_CONNECT(DT_IRQ_ETH_IEEE1588_TMR, DT_ETH_MCUX_0_IRQ_PRI,
eth_mcux_ptp_isr, DEVICE_GET(eth_mcux_0), 0);
irq_enable(DT_IRQ_ETH_IEEE1588_TMR);
#endif
}
#if defined(CONFIG_PTP_CLOCK_MCUX)
struct ptp_context {
struct eth_context *eth_context;
};
static struct ptp_context ptp_mcux_0_context;
static int ptp_clock_mcux_set(struct device *dev, struct net_ptp_time *tm)
{
struct ptp_context *ptp_context = dev->driver_data;
struct eth_context *context = ptp_context->eth_context;
enet_ptp_time_t enet_time;
enet_time.second = tm->second;
enet_time.nanosecond = tm->nanosecond;
ENET_Ptp1588SetTimer(ENET, &context->enet_handle, &enet_time);
return 0;
}
static int ptp_clock_mcux_get(struct device *dev, struct net_ptp_time *tm)
{
struct ptp_context *ptp_context = dev->driver_data;
struct eth_context *context = ptp_context->eth_context;
enet_ptp_time_t enet_time;
ENET_Ptp1588GetTimer(ENET, &context->enet_handle, &enet_time);
tm->second = enet_time.second;
tm->nanosecond = enet_time.nanosecond;
return 0;
}
static int ptp_clock_mcux_adjust(struct device *dev, int increment)
{
int key, ret;
ARG_UNUSED(dev);
if ((increment <= -NSEC_PER_SEC) || (increment >= NSEC_PER_SEC)) {
ret = -EINVAL;
} else {
key = irq_lock();
if (ENET->ATPER != NSEC_PER_SEC) {
ret = -EBUSY;
} else {
/* Seconds counter is handled by software. Change the
* period of one software second to adjust the clock.
*/
ENET->ATPER = NSEC_PER_SEC - increment;
ret = 0;
}
irq_unlock(key);
}
return ret;
}
static int ptp_clock_mcux_rate_adjust(struct device *dev, float ratio)
{
const int hw_inc = NSEC_PER_SEC / CONFIG_ETH_MCUX_PTP_CLOCK_SRC_HZ;
struct ptp_context *ptp_context = dev->driver_data;
struct eth_context *context = ptp_context->eth_context;
int corr;
s32_t mul;
float val;
/* No change needed. */
if (ratio == 1.0) {
return 0;
}
ratio *= context->clk_ratio;
/* Limit possible ratio. */
if ((ratio > 1.0 + 1.0/(2 * hw_inc)) ||
(ratio < 1.0 - 1.0/(2 * hw_inc))) {
return -EINVAL;
}
/* Save new ratio. */
context->clk_ratio = ratio;
if (ratio < 1.0) {
corr = hw_inc - 1;
val = 1.0 / (hw_inc * (1.0 - ratio));
} else if (ratio > 1.0) {
corr = hw_inc + 1;
val = 1.0 / (hw_inc * (ratio-1.0));
} else {
val = 0;
corr = hw_inc;
}
if (val >= INT32_MAX) {
/* Value is too high.
* It is not possible to adjust the rate of the clock.
*/
mul = 0;
} else {
mul = val;
}
ENET_Ptp1588AdjustTimer(ENET, corr, mul);
return 0;
}
static const struct ptp_clock_driver_api api = {
.set = ptp_clock_mcux_set,
.get = ptp_clock_mcux_get,
.adjust = ptp_clock_mcux_adjust,
.rate_adjust = ptp_clock_mcux_rate_adjust,
};
static int ptp_mcux_init(struct device *port)
{
struct device *eth_dev = DEVICE_GET(eth_mcux_0);
struct eth_context *context = eth_dev->driver_data;
struct ptp_context *ptp_context = port->driver_data;
context->ptp_clock = port;
ptp_context->eth_context = context;
return 0;
}
DEVICE_AND_API_INIT(mcux_ptp_clock_0, PTP_CLOCK_NAME, ptp_mcux_init,
&ptp_mcux_0_context, NULL, POST_KERNEL,
CONFIG_APPLICATION_INIT_PRIORITY, &api);
#endif /* CONFIG_PTP_CLOCK_MCUX */