FreeRTOS-Plus/Source/FreeRTOS-Plus-TCP/portable/NetworkInterface/M487/m480_eth.c - third_party/github/FreeRTOS/FreeRTOS-Kernel - Git at Google

 /**************************************************************************//**
  * @copyright (C) 2019 Nuvoton Technology Corp. All rights reserved.
  *
  * Redistribution and use in source and binary forms, with or without modification,
  * are permitted provided that the following conditions are met:
  *   1. Redistributions of source code must retain the above copyright notice,
  *      this list of conditions and the following disclaimer.
  *   2. Redistributions in binary form must reproduce the above copyright notice,
  *      this list of conditions and the following disclaimer in the documentation
  *      and/or other materials provided with the distribution.
  *   3. Neither the name of Nuvoton Technology Corp. nor the names of its contributors
  *      may be used to endorse or promote products derived from this software
  *      without specific prior written permission.
  *
  * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS"
  * AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
  * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE
  * DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS BE LIABLE
  * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
  * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR
  * SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER
  * CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY,
  * OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
  * OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
 *****************************************************************************/
 #include "FreeRTOS.h"
 #include "list.h"
 #include "FreeRTOS_IP.h"

 #include "m480_eth.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;}while(0)
 #define ETH_DISABLE_TX()    do{EMAC->CTL &= ~EMAC_CTL_TXON;}while(0)
 #define ETH_DISABLE_RX()    do{EMAC->CTL &= ~EMAC_CTL_RXON;}while(0)


 struct eth_descriptor rx_desc[RX_DESCRIPTOR_NUM] __attribute__ ((aligned(4)));
 struct eth_descriptor tx_desc[TX_DESCRIPTOR_NUM] __attribute__ ((aligned(4)));
 #ifdef __ICCARM__
 #pragma data_alignment=4
 struct eth_descriptor rx_desc[RX_DESCRIPTOR_NUM];
 struct eth_descriptor tx_desc[TX_DESCRIPTOR_NUM];
 uint8_t rx_buf[RX_DESCRIPTOR_NUM][PACKET_BUFFER_SIZE];
 uint8_t tx_buf[TX_DESCRIPTOR_NUM][PACKET_BUFFER_SIZE];
 #else
 struct eth_descriptor rx_desc[RX_DESCRIPTOR_NUM] __attribute__ ((aligned(4)));
 struct eth_descriptor tx_desc[TX_DESCRIPTOR_NUM] __attribute__ ((aligned(4)));
 uint8_t rx_buf[RX_DESCRIPTOR_NUM][PACKET_BUFFER_SIZE]  __attribute__ ((aligned(4)));
 uint8_t tx_buf[TX_DESCRIPTOR_NUM][PACKET_BUFFER_SIZE]  __attribute__ ((aligned(4)));
 #endif
 struct eth_descriptor volatile *cur_tx_desc_ptr, *cur_rx_desc_ptr, *fin_tx_desc_ptr;


 // 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) {
         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) {
         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);

         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);
         }
     }
 	FreeRTOS_printf(("PHY ID 1:0x%x\r\n", mdio_read(CONFIG_PHY_ADDR, MII_PHYSID1)));
 	FreeRTOS_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) % TX_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);


 }

 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) = 1.25 MHz if system is running at 160 MH
     CLK_SetModuleClock(EMAC_MODULE, 0, CLK_CLKDIV3_EMAC(127));

     /* Update System Core Clock */
     SystemCoreClockUpdate();

     /*---------------------------------------------------------------------------------------------------------*/
     /* Init I/O Multi-function                                                                                 */
     /*---------------------------------------------------------------------------------------------------------*/
     // Configure RMII pins
     SYS->GPA_MFPL &= ~(SYS_GPA_MFPL_PA6MFP_Msk | SYS_GPA_MFPL_PA7MFP_Msk);
     SYS->GPA_MFPL |= SYS_GPA_MFPL_PA6MFP_EMAC_RMII_RXERR | SYS_GPA_MFPL_PA7MFP_EMAC_RMII_CRSDV;
     SYS->GPC_MFPL &= ~(SYS_GPC_MFPL_PC6MFP_Msk | SYS_GPC_MFPL_PC7MFP_Msk);
     SYS->GPC_MFPL |= SYS_GPC_MFPL_PC6MFP_EMAC_RMII_RXD1 | SYS_GPC_MFPL_PC7MFP_EMAC_RMII_RXD0;
     SYS->GPC_MFPH &= ~SYS_GPC_MFPH_PC8MFP_Msk;
     SYS->GPC_MFPH |= SYS_GPC_MFPH_PC8MFP_EMAC_RMII_REFCLK;
     SYS->GPE_MFPH &= ~(SYS_GPE_MFPH_PE8MFP_Msk | SYS_GPE_MFPH_PE9MFP_Msk | SYS_GPE_MFPH_PE10MFP_Msk |
                        SYS_GPE_MFPH_PE11MFP_Msk | SYS_GPE_MFPH_PE12MFP_Msk);
     SYS->GPE_MFPH |= SYS_GPE_MFPH_PE8MFP_EMAC_RMII_MDC |
                     SYS_GPE_MFPH_PE9MFP_EMAC_RMII_MDIO |
                     SYS_GPE_MFPH_PE10MFP_EMAC_RMII_TXD0 |
                     SYS_GPE_MFPH_PE11MFP_EMAC_RMII_TXD1 |
                     SYS_GPE_MFPH_PE12MFP_EMAC_RMII_TXEN;

     // Enable high slew rate on all RMII TX output pins
     PE->SLEWCTL = (GPIO_SLEWCTL_HIGH << GPIO_SLEWCTL_HSREN10_Pos) |
                   (GPIO_SLEWCTL_HIGH << GPIO_SLEWCTL_HSREN11_Pos) |
                   (GPIO_SLEWCTL_HIGH << GPIO_SLEWCTL_HSREN12_Pos);


     /* Lock protected registers */
     SYS_LockReg();


 }

 int numaker_eth_init(uint8_t *mac_addr)
 {
     int ret = 0;
     // 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...


     /* Configure the MAC interrupt enable register. */
     EMAC->INTEN = EMAC_INTEN_RXIEN_Msk |
                   EMAC_INTEN_TXIEN_Msk |
                   EMAC_INTEN_RXGDIEN_Msk |
                   EMAC_INTEN_TXCPIEN_Msk |
                   EMAC_INTEN_RXBEIEN_Msk |
                   EMAC_INTEN_TXBEIEN_Msk |
                   EMAC_INTEN_RDUIEN_Msk |
                   EMAC_INTEN_TSALMIEN_Msk |
                   EMAC_INTEN_WOLIEN_Msk;

     /* Configure the MAC control register. */
     EMAC->CTL = EMAC_CTL_STRIPCRC_Msk | EMAC_CTL_RMIIEN_Msk;

     /* Accept packets for us and all broadcast and multicast packets */
     EMAC->CAMCTL =  EMAC_CAMCTL_CMPEN_Msk |
                     EMAC_CAMCTL_AMP_Msk |
                     EMAC_CAMCTL_ABP_Msk;
     EMAC->CAMEN = 1;    // Enable CAM entry 0

     ret= reset_phy();

     EMAC_ENABLE_RX();
     EMAC_ENABLE_TX();
     return ret;
 }


 void  ETH_halt(void)
 {

     EMAC->CTL &= ~(EMAC_CTL_RXON_Msk | EMAC_CTL_TXON_Msk);
 }

 unsigned int m_status;

 void EMAC_RX_IRQHandler(void)
 {
 //    NU_DEBUGF(("%s ... \r\n", __FUNCTION__));
     m_status = EMAC->INTSTS & 0xFFFF;
     EMAC->INTSTS = m_status;
     if (m_status & EMAC_INTSTS_RXBEIF_Msk) {
         // Shouldn't goes here, unless descriptor corrupted
 		NU_DEBUGF(("RX descriptor corrupted \r\n"));
 		//return;
     }
     // FIX ME: for rx-event, to ack rx_isr into event queue
         xNetworkCallback('R');
 }


 void numaker_eth_trigger_rx(void)
 {
     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;
     }
     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
         return;
     }

     cur_entry = EMAC->CTXDSA;

     while (cur_entry != (uint32_t)fin_tx_desc_ptr) {

         fin_tx_desc_ptr = fin_tx_desc_ptr->next;
     }
     // FIX ME: for tx-event, no-op at this stage
     xNetworkCallback('T');
 }

 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;
 //}

 // Provide ethernet devices with a semi-unique MAC address
 void numaker_mac_address(uint8_t *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);
 }
	/************************************************************************//
	* @copyright (C) 2019 Nuvoton Technology Corp. All rights reserved.
	*
	* Redistribution and use in source and binary forms, with or without modification,
	* are permitted provided that the following conditions are met:
	* 1. Redistributions of source code must retain the above copyright notice,
	* this list of conditions and the following disclaimer.
	* 2. Redistributions in binary form must reproduce the above copyright notice,
	* this list of conditions and the following disclaimer in the documentation
	* and/or other materials provided with the distribution.
	* 3. Neither the name of Nuvoton Technology Corp. nor the names of its contributors
	* may be used to endorse or promote products derived from this software
	* without specific prior written permission.
	*
	* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS"
	* AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
	* IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE
	* DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS BE LIABLE
	* FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
	* DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR
	* SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER
	* CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY,
	* OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
	* OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
	*****************************************************************************/
	#include "FreeRTOS.h"
	#include "list.h"
	#include "FreeRTOS_IP.h"

	#include "m480_eth.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;}while(0)
	#define ETH_DISABLE_TX() do{EMAC->CTL &= ~EMAC_CTL_TXON;}while(0)
	#define ETH_DISABLE_RX() do{EMAC->CTL &= ~EMAC_CTL_RXON;}while(0)


	struct eth_descriptor rx_desc[RX_DESCRIPTOR_NUM] __attribute__ ((aligned(4)));
	struct eth_descriptor tx_desc[TX_DESCRIPTOR_NUM] __attribute__ ((aligned(4)));
	#ifdef __ICCARM__
	#pragma data_alignment=4
	struct eth_descriptor rx_desc[RX_DESCRIPTOR_NUM];
	struct eth_descriptor tx_desc[TX_DESCRIPTOR_NUM];
	uint8_t rx_buf[RX_DESCRIPTOR_NUM][PACKET_BUFFER_SIZE];
	uint8_t tx_buf[TX_DESCRIPTOR_NUM][PACKET_BUFFER_SIZE];
	#else
	struct eth_descriptor rx_desc[RX_DESCRIPTOR_NUM] __attribute__ ((aligned(4)));
	struct eth_descriptor tx_desc[TX_DESCRIPTOR_NUM] __attribute__ ((aligned(4)));
	uint8_t rx_buf[RX_DESCRIPTOR_NUM][PACKET_BUFFER_SIZE] __attribute__ ((aligned(4)));
	uint8_t tx_buf[TX_DESCRIPTOR_NUM][PACKET_BUFFER_SIZE] __attribute__ ((aligned(4)));
	#endif
	struct eth_descriptor volatile cur_tx_desc_ptr, cur_rx_desc_ptr, *fin_tx_desc_ptr;


	// 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) {
	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) {
	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);

	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);
	}
	}
	FreeRTOS_printf(("PHY ID 1:0x%x\r\n", mdio_read(CONFIG_PHY_ADDR, MII_PHYSID1)));
	FreeRTOS_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) % TX_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);


	}

	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) = 1.25 MHz if system is running at 160 MH
	CLK_SetModuleClock(EMAC_MODULE, 0, CLK_CLKDIV3_EMAC(127));

	/* Update System Core Clock */
	SystemCoreClockUpdate();

	/---------------------------------------------------------------------------------------------------------/
	/* Init I/O Multi-function */
	/---------------------------------------------------------------------------------------------------------/
	// Configure RMII pins
	SYS->GPA_MFPL &= ~(SYS_GPA_MFPL_PA6MFP_Msk \| SYS_GPA_MFPL_PA7MFP_Msk);
	SYS->GPA_MFPL \|= SYS_GPA_MFPL_PA6MFP_EMAC_RMII_RXERR \| SYS_GPA_MFPL_PA7MFP_EMAC_RMII_CRSDV;
	SYS->GPC_MFPL &= ~(SYS_GPC_MFPL_PC6MFP_Msk \| SYS_GPC_MFPL_PC7MFP_Msk);
	SYS->GPC_MFPL \|= SYS_GPC_MFPL_PC6MFP_EMAC_RMII_RXD1 \| SYS_GPC_MFPL_PC7MFP_EMAC_RMII_RXD0;
	SYS->GPC_MFPH &= ~SYS_GPC_MFPH_PC8MFP_Msk;
	SYS->GPC_MFPH \|= SYS_GPC_MFPH_PC8MFP_EMAC_RMII_REFCLK;
	SYS->GPE_MFPH &= ~(SYS_GPE_MFPH_PE8MFP_Msk \| SYS_GPE_MFPH_PE9MFP_Msk \| SYS_GPE_MFPH_PE10MFP_Msk \|
	SYS_GPE_MFPH_PE11MFP_Msk \| SYS_GPE_MFPH_PE12MFP_Msk);
	SYS->GPE_MFPH \|= SYS_GPE_MFPH_PE8MFP_EMAC_RMII_MDC \|
	SYS_GPE_MFPH_PE9MFP_EMAC_RMII_MDIO \|
	SYS_GPE_MFPH_PE10MFP_EMAC_RMII_TXD0 \|
	SYS_GPE_MFPH_PE11MFP_EMAC_RMII_TXD1 \|
	SYS_GPE_MFPH_PE12MFP_EMAC_RMII_TXEN;

	// Enable high slew rate on all RMII TX output pins
	PE->SLEWCTL = (GPIO_SLEWCTL_HIGH << GPIO_SLEWCTL_HSREN10_Pos) \|
	(GPIO_SLEWCTL_HIGH << GPIO_SLEWCTL_HSREN11_Pos) \|
	(GPIO_SLEWCTL_HIGH << GPIO_SLEWCTL_HSREN12_Pos);


	/* Lock protected registers */
	SYS_LockReg();


	}

	int numaker_eth_init(uint8_t *mac_addr)
	{
	int ret = 0;
	// 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...


	/* Configure the MAC interrupt enable register. */
	EMAC->INTEN = EMAC_INTEN_RXIEN_Msk \|
	EMAC_INTEN_TXIEN_Msk \|
	EMAC_INTEN_RXGDIEN_Msk \|
	EMAC_INTEN_TXCPIEN_Msk \|
	EMAC_INTEN_RXBEIEN_Msk \|
	EMAC_INTEN_TXBEIEN_Msk \|
	EMAC_INTEN_RDUIEN_Msk \|
	EMAC_INTEN_TSALMIEN_Msk \|
	EMAC_INTEN_WOLIEN_Msk;

	/* Configure the MAC control register. */
	EMAC->CTL = EMAC_CTL_STRIPCRC_Msk \| EMAC_CTL_RMIIEN_Msk;

	/* Accept packets for us and all broadcast and multicast packets */
	EMAC->CAMCTL = EMAC_CAMCTL_CMPEN_Msk \|
	EMAC_CAMCTL_AMP_Msk \|
	EMAC_CAMCTL_ABP_Msk;
	EMAC->CAMEN = 1; // Enable CAM entry 0

	ret= reset_phy();

	EMAC_ENABLE_RX();
	EMAC_ENABLE_TX();
	return ret;
	}



	void ETH_halt(void)
	{

	EMAC->CTL &= ~(EMAC_CTL_RXON_Msk \| EMAC_CTL_TXON_Msk);
	}

	unsigned int m_status;

	void EMAC_RX_IRQHandler(void)
	{
	// NU_DEBUGF(("%s ... \r\n", __FUNCTION__));
	m_status = EMAC->INTSTS & 0xFFFF;
	EMAC->INTSTS = m_status;
	if (m_status & EMAC_INTSTS_RXBEIF_Msk) {
	// Shouldn't goes here, unless descriptor corrupted
	NU_DEBUGF(("RX descriptor corrupted \r\n"));
	//return;
	}
	// FIX ME: for rx-event, to ack rx_isr into event queue
	xNetworkCallback('R');
	}


	void numaker_eth_trigger_rx(void)
	{
	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;
	}
	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
	return;
	}

	cur_entry = EMAC->CTXDSA;

	while (cur_entry != (uint32_t)fin_tx_desc_ptr) {

	fin_tx_desc_ptr = fin_tx_desc_ptr->next;
	}
	// FIX ME: for tx-event, no-op at this stage
	xNetworkCallback('T');
	}

	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;
	//}

	// Provide ethernet devices with a semi-unique MAC address
	void numaker_mac_address(uint8_t *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);
	}