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Import Mbed OS hard-float snapshot

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Beslan
2026-06-01 20:15:04 +03:00
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479
connectivity/drivers/emac/TARGET_NUVOTON_EMAC/TARGET_NUC472/nuc472_eth.c Normal file
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/*
* Copyright (c) 2018 Nuvoton Technology Corp.
* Copyright (c) 2018 ARM Limited
*
* Licensed under the Apache License, Version 2.0 (the "License");
* you may not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*
* Description: NUC472 MAC driver source file
*/
#include <stdbool.h>
#include "nuc472_eth.h"
#include "mbed_toolchain.h"
//#define NU_TRACE
#include "numaker_eth_hal.h"
#define ETH_TRIGGER_RX() do{EMAC->RXST = 0;}while(0)
#define ETH_TRIGGER_TX() do{EMAC->TXST = 0;}while(0)
#define ETH_ENABLE_TX() do{EMAC->CTL |= EMAC_CTL_TXON;}while(0)
#define ETH_ENABLE_RX() do{EMAC->CTL |= EMAC_CTL_RXON_Msk;}while(0)
#define ETH_DISABLE_TX() do{EMAC->CTL &= ~EMAC_CTL_TXON;}while(0)
#define ETH_DISABLE_RX() do{EMAC->CTL &= ~EMAC_CTL_RXON_Msk;}while(0)
#define EMAC_ENABLE_INT(emac, u32eIntSel) ((emac)->INTEN |= (u32eIntSel))
#define EMAC_DISABLE_INT(emac, u32eIntSel) ((emac)->INTEN &= ~ (u32eIntSel))
MBED_ALIGN(4) struct eth_descriptor rx_desc[RX_DESCRIPTOR_NUM];
MBED_ALIGN(4) struct eth_descriptor tx_desc[TX_DESCRIPTOR_NUM];
struct eth_descriptor volatile *cur_tx_desc_ptr, *cur_rx_desc_ptr, *fin_tx_desc_ptr;
__attribute__((section("EMAC_RAM")))
MBED_ALIGN(4) uint8_t rx_buf[RX_DESCRIPTOR_NUM][PACKET_BUFFER_SIZE];
__attribute__((section("EMAC_RAM")))
MBED_ALIGN(4) uint8_t tx_buf[TX_DESCRIPTOR_NUM][PACKET_BUFFER_SIZE];
eth_callback_t nu_eth_txrx_cb = NULL;
void *nu_userData = NULL;
extern void ack_emac_rx_isr(void);
static bool isPhyReset = false;
static uint16_t phyLPAval = 0;
// PTP source clock is 84MHz (Real chip using PLL). Each tick is 11.90ns
// Assume we want to set each tick to 100ns.
// Increase register = (100 * 2^31) / (10^9) = 214.71 =~ 215 = 0xD7
// Addend register = 2^32 * tick_freq / (84MHz), where tick_freq = (2^31 / 215) MHz
// From above equation, addend register = 2^63 / (84M * 215) ~= 510707200 = 0x1E70C600
static void mdio_write(uint8_t addr, uint8_t reg, uint16_t val)
{
EMAC->MIIMDAT = val;
EMAC->MIIMCTL = (addr << EMAC_MIIMCTL_PHYADDR_Pos) | reg | EMAC_MIIMCTL_BUSY_Msk | EMAC_MIIMCTL_WRITE_Msk | EMAC_MIIMCTL_MDCON_Msk;
while (EMAC->MIIMCTL & EMAC_MIIMCTL_BUSY_Msk);
}
static uint16_t mdio_read(uint8_t addr, uint8_t reg)
{
EMAC->MIIMCTL = (addr << EMAC_MIIMCTL_PHYADDR_Pos) | reg | EMAC_MIIMCTL_BUSY_Msk | EMAC_MIIMCTL_MDCON_Msk;
while (EMAC->MIIMCTL & EMAC_MIIMCTL_BUSY_Msk);
return (EMAC->MIIMDAT);
}
static int reset_phy(void)
{
uint16_t reg;
uint32_t delayCnt;
mdio_write(CONFIG_PHY_ADDR, MII_BMCR, BMCR_RESET);
delayCnt = 2000;
while (delayCnt > 0) {
delayCnt--;
if ((mdio_read(CONFIG_PHY_ADDR, MII_BMCR) & BMCR_RESET) == 0) {
break;
}
}
if (delayCnt == 0) {
NU_DEBUGF(("Reset phy failed\n"));
return (-1);
}
mdio_write(CONFIG_PHY_ADDR, MII_ADVERTISE, ADVERTISE_CSMA |
ADVERTISE_10HALF |
ADVERTISE_10FULL |
ADVERTISE_100HALF |
ADVERTISE_100FULL);
reg = mdio_read(CONFIG_PHY_ADDR, MII_BMCR);
mdio_write(CONFIG_PHY_ADDR, MII_BMCR, reg | BMCR_ANRESTART);
delayCnt = 200000;
while (delayCnt > 0) {
delayCnt--;
if ((mdio_read(CONFIG_PHY_ADDR, MII_BMSR) & (BMSR_ANEGCOMPLETE | BMSR_LSTATUS))
== (BMSR_ANEGCOMPLETE | BMSR_LSTATUS)) {
break;
}
}
if (delayCnt == 0) {
NU_DEBUGF(("AN failed. Set to 100 FULL\n"));
EMAC->CTL |= (EMAC_CTL_OPMODE_Msk | EMAC_CTL_FUDUP_Msk);
return (-1);
} else {
reg = mdio_read(CONFIG_PHY_ADDR, MII_LPA);
phyLPAval = reg;
if (reg & ADVERTISE_100FULL) {
NU_DEBUGF(("100 full\n"));
EMAC->CTL |= (EMAC_CTL_OPMODE_Msk | EMAC_CTL_FUDUP_Msk);
} else if (reg & ADVERTISE_100HALF) {
NU_DEBUGF(("100 half\n"));
EMAC->CTL = (EMAC->CTL & ~EMAC_CTL_FUDUP_Msk) | EMAC_CTL_OPMODE_Msk;
} else if (reg & ADVERTISE_10FULL) {
NU_DEBUGF(("10 full\n"));
EMAC->CTL = (EMAC->CTL & ~EMAC_CTL_OPMODE_Msk) | EMAC_CTL_FUDUP_Msk;
} else {
NU_DEBUGF(("10 half\n"));
EMAC->CTL &= ~(EMAC_CTL_OPMODE_Msk | EMAC_CTL_FUDUP_Msk);
}
}
printf("PHY ID 1:0x%x\r\n", mdio_read(CONFIG_PHY_ADDR, MII_PHYSID1));
printf("PHY ID 2:0x%x\r\n", mdio_read(CONFIG_PHY_ADDR, MII_PHYSID2));
return (0);
}
static void init_tx_desc(void)
{
uint32_t i;
cur_tx_desc_ptr = fin_tx_desc_ptr = &tx_desc[0];
for (i = 0; i < TX_DESCRIPTOR_NUM; i++) {
tx_desc[i].status1 = TXFD_PADEN | TXFD_CRCAPP | TXFD_INTEN;
tx_desc[i].buf = &tx_buf[i][0];
tx_desc[i].status2 = 0;
tx_desc[i].next = &tx_desc[(i + 1) % TX_DESCRIPTOR_NUM];
}
EMAC->TXDSA = (unsigned int)&tx_desc[0];
return;
}
static void init_rx_desc(void)
{
uint32_t i;
cur_rx_desc_ptr = &rx_desc[0];
for (i = 0; i < RX_DESCRIPTOR_NUM; i++) {
rx_desc[i].status1 = OWNERSHIP_EMAC;
rx_desc[i].buf = &rx_buf[i][0];
rx_desc[i].status2 = 0;
rx_desc[i].next = &rx_desc[(i + 1) % (RX_DESCRIPTOR_NUM)];
}
EMAC->RXDSA = (unsigned int)&rx_desc[0];
return;
}
void numaker_set_mac_addr(uint8_t *addr)
{
EMAC->CAM0M = (addr[0] << 24) |
(addr[1] << 16) |
(addr[2] << 8) |
addr[3];
EMAC->CAM0L = (addr[4] << 24) |
(addr[5] << 16);
EMAC->CAMCTL = EMAC_CAMCTL_CMPEN_Msk | EMAC_CAMCTL_AMP_Msk | EMAC_CAMCTL_ABP_Msk;
EMAC->CAMEN = 1; // Enable CAM entry 0
}
static void __eth_clk_pin_init()
{
/* Unlock protected registers */
SYS_UnlockReg();
/* Enable IP clock */
CLK_EnableModuleClock(EMAC_MODULE);
// Configure MDC clock rate to HCLK / (127 + 1) = 656 kHz if system is running at 84 MHz
CLK_SetModuleClock(EMAC_MODULE, 0, CLK_CLKDIV3_EMAC(127));
/* Update System Core Clock */
SystemCoreClockUpdate();
/*---------------------------------------------------------------------------------------------------------*/
/* Init I/O Multi-function */
/*---------------------------------------------------------------------------------------------------------*/
// Configure RMII pins
SYS->GPC_MFPL &= ~(SYS_GPC_MFPL_PC0MFP_Msk | SYS_GPC_MFPL_PC1MFP_Msk |
SYS_GPC_MFPL_PC2MFP_Msk | SYS_GPC_MFPL_PC3MFP_Msk |
SYS_GPC_MFPL_PC4MFP_Msk | SYS_GPC_MFPL_PC6MFP_Msk | SYS_GPC_MFPL_PC7MFP_Msk);
SYS->GPC_MFPL |= SYS_GPC_MFPL_PC0MFP_EMAC_REFCLK |
SYS_GPC_MFPL_PC1MFP_EMAC_MII_RXERR |
SYS_GPC_MFPL_PC2MFP_EMAC_MII_RXDV |
SYS_GPC_MFPL_PC3MFP_EMAC_MII_RXD1 |
SYS_GPC_MFPL_PC4MFP_EMAC_MII_RXD0 |
SYS_GPC_MFPL_PC6MFP_EMAC_MII_TXD0 |
SYS_GPC_MFPL_PC7MFP_EMAC_MII_TXD1;
SYS->GPC_MFPH &= ~SYS_GPC_MFPH_PC8MFP_Msk;
SYS->GPC_MFPH |= SYS_GPC_MFPH_PC8MFP_EMAC_MII_TXEN;
// Enable high slew rate on all RMII pins
PC->SLEWCTL |= 0x1DF;
// Configure MDC, MDIO at PB14 & PB15
SYS->GPB_MFPH &= ~(SYS_GPB_MFPH_PB14MFP_Msk | SYS_GPB_MFPH_PB15MFP_Msk);
SYS->GPB_MFPH |= SYS_GPB_MFPH_PB14MFP_EMAC_MII_MDC | SYS_GPB_MFPH_PB15MFP_EMAC_MII_MDIO;
/* Lock protected registers */
SYS_LockReg();
}
void numaker_eth_init(uint8_t *mac_addr)
{
// init CLK & pins
__eth_clk_pin_init();
// Reset MAC
EMAC->CTL = EMAC_CTL_RST_Msk;
while (EMAC->CTL & EMAC_CTL_RST_Msk) {}
init_tx_desc();
init_rx_desc();
numaker_set_mac_addr(mac_addr); // need to reconfigure hardware address 'cos we just RESET emc...
EMAC->CTL |= EMAC_CTL_STRIPCRC_Msk | EMAC_CTL_RXON_Msk | EMAC_CTL_TXON_Msk | EMAC_CTL_RMIIEN_Msk | EMAC_CTL_RMIIRXCTL_Msk;
EMAC->INTEN |= EMAC_INTEN_RXIEN_Msk |
EMAC_INTEN_RXGDIEN_Msk |
EMAC_INTEN_RDUIEN_Msk |
EMAC_INTEN_RXBEIEN_Msk |
EMAC_INTEN_TXIEN_Msk |
EMAC_INTEN_TXABTIEN_Msk |
EMAC_INTEN_TXCPIEN_Msk |
EMAC_INTEN_TXBEIEN_Msk;
/* Limit the max receive frame length to 1514 + 4 */
EMAC->MRFL = NU_ETH_MAX_FLEN;
/* Set RX FIFO threshold as 8 words */
if (isPhyReset != true) {
if (!reset_phy()) {
isPhyReset = true;
}
} else {
if (phyLPAval & ADVERTISE_100FULL) {
NU_DEBUGF(("100 full\n"));
EMAC->CTL |= (EMAC_CTL_OPMODE_Msk | EMAC_CTL_FUDUP_Msk);
} else if (phyLPAval & ADVERTISE_100HALF) {
NU_DEBUGF(("100 half\n"));
EMAC->CTL = (EMAC->CTL & ~EMAC_CTL_FUDUP_Msk) | EMAC_CTL_OPMODE_Msk;
} else if (phyLPAval & ADVERTISE_10FULL) {
NU_DEBUGF(("10 full\n"));
EMAC->CTL = (EMAC->CTL & ~EMAC_CTL_OPMODE_Msk) | EMAC_CTL_FUDUP_Msk;
} else {
NU_DEBUGF(("10 half\n"));
EMAC->CTL &= ~(EMAC_CTL_OPMODE_Msk | EMAC_CTL_FUDUP_Msk);
}
}
EMAC_ENABLE_RX();
EMAC_ENABLE_TX();
}
void ETH_halt(void)
{
EMAC->CTL &= ~(EMAC_CTL_RXON_Msk | EMAC_CTL_TXON_Msk);
}
unsigned int m_status;
void EMAC_RX_IRQHandler(void)
{
m_status = EMAC->INTSTS & 0xFFFF;
EMAC->INTSTS = m_status;
if (m_status & EMAC_INTSTS_RXBEIF_Msk) {
// Shouldn't goes here, unless descriptor corrupted
mbed_error_printf("### RX Bus error [0x%x]\r\n", m_status);
if (nu_eth_txrx_cb != NULL) {
nu_eth_txrx_cb('B', nu_userData);
}
return;
}
EMAC_DISABLE_INT(EMAC, (EMAC_INTEN_RDUIEN_Msk | EMAC_INTEN_RXGDIEN_Msk));
if (nu_eth_txrx_cb != NULL) {
nu_eth_txrx_cb('R', nu_userData);
}
}
void numaker_eth_trigger_rx(void)
{
EMAC_ENABLE_INT(EMAC, (EMAC_INTEN_RDUIEN_Msk | EMAC_INTEN_RXGDIEN_Msk));
ETH_TRIGGER_RX();
}
int numaker_eth_get_rx_buf(uint16_t *len, uint8_t **buf)
{
unsigned int cur_entry, status;
cur_entry = EMAC->CRXDSA;
if ((cur_entry == (uint32_t)cur_rx_desc_ptr) && (!(m_status & EMAC_INTSTS_RDUIF_Msk))) { // cur_entry may equal to cur_rx_desc_ptr if RDU occures
return -1;
}
status = cur_rx_desc_ptr->status1;
if (status & OWNERSHIP_EMAC) {
return -1;
}
if (status & RXFD_RXGD) {
*buf = cur_rx_desc_ptr->buf;
*len = status & 0xFFFF;
// length of payload should be <= 1514
if (*len > (NU_ETH_MAX_FLEN - 4)) {
NU_DEBUGF(("%s... unexpected long packet length=%d, buf=0x%x\r\n", __FUNCTION__, *len, *buf));
*len = 0; // Skip this unexpected long packet
}
if (*len == (NU_ETH_MAX_FLEN - 4)) {
NU_DEBUGF(("%s... length=%d, buf=0x%x\r\n", __FUNCTION__, *len, *buf));
}
}
return 0;
}
void numaker_eth_rx_next(void)
{
cur_rx_desc_ptr->status1 = OWNERSHIP_EMAC;
cur_rx_desc_ptr = cur_rx_desc_ptr->next;
}
void EMAC_TX_IRQHandler(void)
{
unsigned int cur_entry, status;
status = EMAC->INTSTS & 0xFFFF0000;
EMAC->INTSTS = status;
if (status & EMAC_INTSTS_TXBEIF_Msk) {
// Shouldn't goes here, unless descriptor corrupted
mbed_error_printf("### TX Bus error [0x%x]\r\n", status);
if (nu_eth_txrx_cb != NULL) {
nu_eth_txrx_cb('B', nu_userData);
}
return;
}
cur_entry = EMAC->CTXDSA;
while (cur_entry != (uint32_t)fin_tx_desc_ptr) {
fin_tx_desc_ptr = fin_tx_desc_ptr->next;
}
if (nu_eth_txrx_cb != NULL) {
nu_eth_txrx_cb('T', nu_userData);
}
}
uint8_t *numaker_eth_get_tx_buf(void)
{
if (cur_tx_desc_ptr->status1 & OWNERSHIP_EMAC) {
return (NULL);
} else {
return (cur_tx_desc_ptr->buf);
}
}
void numaker_eth_trigger_tx(uint16_t length, void *p)
{
struct eth_descriptor volatile *desc;
cur_tx_desc_ptr->status2 = (unsigned int)length;
desc = cur_tx_desc_ptr->next; // in case TX is transmitting and overwrite next pointer before we can update cur_tx_desc_ptr
cur_tx_desc_ptr->status1 |= OWNERSHIP_EMAC;
cur_tx_desc_ptr = desc;
ETH_TRIGGER_TX();
}
int numaker_eth_link_ok(void)
{
/* first, a dummy read to latch */
mdio_read(CONFIG_PHY_ADDR, MII_BMSR);
if (mdio_read(CONFIG_PHY_ADDR, MII_BMSR) & BMSR_LSTATUS) {
return 1;
}
return 0;
}
void numaker_eth_set_cb(eth_callback_t eth_cb, void *userData)
{
nu_eth_txrx_cb = eth_cb;
nu_userData = userData;
}
// Override mbed_mac_address of mbed_interface.c to provide ethernet devices with a semi-unique MAC address
void mbed_mac_address(char *mac)
{
uint32_t uID1;
// Fetch word 0
uint32_t word0 = *(uint32_t *)0x7F804; // 2KB Data Flash at 0x7F800
// Fetch word 1
// we only want bottom 16 bits of word1 (MAC bits 32-47)
// and bit 9 forced to 1, bit 8 forced to 0
// Locally administered MAC, reduced conflicts
// http://en.wikipedia.org/wiki/MAC_address
uint32_t word1 = *(uint32_t *)0x7F800; // 2KB Data Flash at 0x7F800
if (word0 == 0xFFFFFFFF) { // Not burn any mac address at 1st 2 words of Data Flash
// with a semi-unique MAC address from the UUID
/* Enable FMC ISP function */
SYS_UnlockReg();
FMC_Open();
// = FMC_ReadUID(0);
uID1 = FMC_ReadUID(1);
word1 = (uID1 & 0x003FFFFF) | ((uID1 & 0x030000) << 6) >> 8;
word0 = ((FMC_ReadUID(0) >> 4) << 20) | ((uID1 & 0xFF) << 12) | (FMC_ReadUID(2) & 0xFFF);
/* Disable FMC ISP function */
FMC_Close();
/* Lock protected registers */
SYS_LockReg();
}
word1 |= 0x00000200;
word1 &= 0x0000FEFF;
mac[0] = (word1 & 0x0000ff00) >> 8;
mac[1] = (word1 & 0x000000ff);
mac[2] = (word0 & 0xff000000) >> 24;
mac[3] = (word0 & 0x00ff0000) >> 16;
mac[4] = (word0 & 0x0000ff00) >> 8;
mac[5] = (word0 & 0x000000ff);
NU_DEBUGF(("mac address %02x-%02x-%02x-%02x-%02x-%02x \r\n", mac[0], mac[1], mac[2], mac[3], mac[4], mac[5]));
}
void numaker_eth_enable_interrupts(void)
{
EMAC->INTEN |= EMAC_INTEN_RXIEN_Msk |
EMAC_INTEN_TXIEN_Msk ;
NVIC_EnableIRQ(EMAC_RX_IRQn);
NVIC_EnableIRQ(EMAC_TX_IRQn);
}
void numaker_eth_disable_interrupts(void)
{
NVIC_DisableIRQ(EMAC_RX_IRQn);
NVIC_DisableIRQ(EMAC_TX_IRQn);
}

140
connectivity/drivers/emac/TARGET_NUVOTON_EMAC/TARGET_NUC472/nuc472_eth.h Normal file
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/*
* Copyright (c) 2018 Nuvoton Technology Corp.
* Copyright (c) 2018 ARM Limited
*
* Licensed under the Apache License, Version 2.0 (the "License");
* you may not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*
* Description: NUC472 EMAC driver header file
*/
#include "NUC472_442.h"
#include "numaker_emac_config.h"
#ifndef _NUC472_ETH_
#define _NUC472_ETH_
/* Generic MII registers. */
#define MII_BMCR 0x00 /* Basic mode control register */
#define MII_BMSR 0x01 /* Basic mode status register */
#define MII_PHYSID1 0x02 /* PHYS ID 1 */
#define MII_PHYSID2 0x03 /* PHYS ID 2 */
#define MII_ADVERTISE 0x04 /* Advertisement control reg */
#define MII_LPA 0x05 /* Link partner ability reg */
#define MII_EXPANSION 0x06 /* Expansion register */
#define MII_DCOUNTER 0x12 /* Disconnect counter */
#define MII_FCSCOUNTER 0x13 /* False carrier counter */
#define MII_NWAYTEST 0x14 /* N-way auto-neg test reg */
#define MII_RERRCOUNTER 0x15 /* Receive error counter */
#define MII_SREVISION 0x16 /* Silicon revision */
#define MII_RESV1 0x17 /* Reserved... */
#define MII_LBRERROR 0x18 /* Lpback, rx, bypass error */
#define MII_PHYADDR 0x19 /* PHY address */
#define MII_RESV2 0x1a /* Reserved... */
#define MII_TPISTATUS 0x1b /* TPI status for 10mbps */
#define MII_NCONFIG 0x1c /* Network interface config */
/* Basic mode control register. */
#define BMCR_RESV 0x007f /* Unused... */
#define BMCR_CTST 0x0080 /* Collision test */
#define BMCR_FULLDPLX 0x0100 /* Full duplex */
#define BMCR_ANRESTART 0x0200 /* Auto negotiation restart */
#define BMCR_ISOLATE 0x0400 /* Disconnect DP83840 from MII */
#define BMCR_PDOWN 0x0800 /* Powerdown the DP83840 */
#define BMCR_ANENABLE 0x1000 /* Enable auto negotiation */
#define BMCR_SPEED100 0x2000 /* Select 100Mbps */
#define BMCR_LOOPBACK 0x4000 /* TXD loopback bits */
#define BMCR_RESET 0x8000 /* Reset the DP83840 */
/* Basic mode status register. */
#define BMSR_ERCAP 0x0001 /* Ext-reg capability */
#define BMSR_JCD 0x0002 /* Jabber detected */
#define BMSR_LSTATUS 0x0004 /* Link status */
#define BMSR_ANEGCAPABLE 0x0008 /* Able to do auto-negotiation */
#define BMSR_RFAULT 0x0010 /* Remote fault detected */
#define BMSR_ANEGCOMPLETE 0x0020 /* Auto-negotiation complete */
#define BMSR_RESV 0x07c0 /* Unused... */
#define BMSR_10HALF 0x0800 /* Can do 10mbps, half-duplex */
#define BMSR_10FULL 0x1000 /* Can do 10mbps, full-duplex */
#define BMSR_100HALF 0x2000 /* Can do 100mbps, half-duplex */
#define BMSR_100FULL 0x4000 /* Can do 100mbps, full-duplex */
#define BMSR_100BASE4 0x8000 /* Can do 100mbps, 4k packets */
/* Advertisement control register. */
#define ADVERTISE_SLCT 0x001f /* Selector bits */
#define ADVERTISE_CSMA 0x0001 /* Only selector supported */
#define ADVERTISE_10HALF 0x0020 /* Try for 10mbps half-duplex */
#define ADVERTISE_10FULL 0x0040 /* Try for 10mbps full-duplex */
#define ADVERTISE_100HALF 0x0080 /* Try for 100mbps half-duplex */
#define ADVERTISE_100FULL 0x0100 /* Try for 100mbps full-duplex */
#define ADVERTISE_100BASE4 0x0200 /* Try for 100mbps 4k packets */
#define ADVERTISE_RESV 0x1c00 /* Unused... */
#define ADVERTISE_RFAULT 0x2000 /* Say we can detect faults */
#define ADVERTISE_LPACK 0x4000 /* Ack link partners response */
#define ADVERTISE_NPAGE 0x8000 /* Next page bit */
#define RX_DESCRIPTOR_NUM NU_RX_RING_LEN//4 //2 // 4: Max Number of Rx Frame Descriptors
#define TX_DESCRIPTOR_NUM NU_TX_RING_LEN//4 //2 // 4: Max number of Tx Frame Descriptors
#define PACKET_BUFFER_SIZE ( NU_ETH_MAX_FLEN + ((NU_ETH_MAX_FLEN%4) ? (4 - (NU_ETH_MAX_FLEN%4)) : 0) ) //For DMA 4 bytes alignment
#define CONFIG_PHY_ADDR 1
// Frame Descriptor's Owner bit
#define OWNERSHIP_EMAC 0x80000000 // 1 = EMAC
//#define OWNERSHIP_CPU 0x7fffffff // 0 = CPU
// Rx Frame Descriptor Status
#define RXFD_RXGD 0x00100000 // Receiving Good Packet Received
#define RXFD_RTSAS 0x00800000 // RX Time Stamp Available
// Tx Frame Descriptor's Control bits
#define TXFD_TTSEN 0x08 // Tx Time Stamp Enable
#define TXFD_INTEN 0x04 // Interrupt Enable
#define TXFD_CRCAPP 0x02 // Append CRC
#define TXFD_PADEN 0x01 // Padding Enable
// Tx Frame Descriptor Status
#define TXFD_TXCP 0x00080000 // Transmission Completion
#define TXFD_TTSAS 0x08000000 // TX Time Stamp Available
// Tx/Rx buffer descriptor structure
struct eth_descriptor;
struct eth_descriptor {
uint32_t status1;
uint8_t *buf;
uint32_t status2;
struct eth_descriptor *next;
#ifdef TIME_STAMPING
uint32_t backup1;
uint32_t backup2;
uint32_t reserved1;
uint32_t reserved2;
#endif
};
#ifdef TIME_STAMPING
#define ETH_TS_ENABLE() do{EMAC->TSCTL = EMAC_TSCTL_TSEN_Msk;}while(0)
#define ETH_TS_START() do{EMAC->TSCTL |= (EMAC_TSCTL_TSMODE_Msk | EMAC_TSCTL_TSIEN_Msk);}while(0)
s32_t ETH_settime(u32_t sec, u32_t nsec);
s32_t ETH_gettime(u32_t *sec, u32_t *nsec);
s32_t ETH_updatetime(u32_t neg, u32_t sec, u32_t nsec);
s32_t ETH_adjtimex(int ppm);
void ETH_setinc(void);
#endif
#endif /* _NUC472_ETH_ */