Google Git
Sign in
pigweed / third_party / github / FreeRTOS / FreeRTOS-Kernel / 9c0c37ab9b56f2c90085b78df2f58b5833e473db / . / FreeRTOS-Plus / Source / FreeRTOS-Plus-TCP / portable / NetworkInterface / ATSAM4E / ethernet_phy.c
blob: fe9e2960ff80b754834c4c51ae7b1a3ac322b158 [file] [log] [blame]
/**
* \file
*
* \brief API driver for KSZ8051MNL PHY component.
*
* Copyright (c) 2013 Atmel Corporation. All rights reserved.
*
* \asf_license_start
*
* \page License
*
* 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. The name of Atmel may not be used to endorse or promote products derived
* from this software without specific prior written permission.
*
* 4. This software may only be redistributed and used in connection with an
* Atmel microcontroller product.
*
* THIS SOFTWARE IS PROVIDED BY ATMEL "AS IS" AND ANY EXPRESS OR IMPLIED
* WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF
* MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NON-INFRINGEMENT ARE
* EXPRESSLY AND SPECIFICALLY DISCLAIMED. IN NO EVENT SHALL ATMEL 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.
*
* \asf_license_stop
*
*/
/* Standard includes. */
#include <stdint.h>
#include <stdio.h>
#include <stdlib.h>
/* FreeRTOS includes. */
#include "FreeRTOS.h"
#include "FreeRTOSIPConfig.h"
#include "ethernet_phy.h"
#include "instance/gmac.h"
/// @cond 0
/**INDENT-OFF**/
#ifdef __cplusplus
extern "C" {
#endif
/**INDENT-ON**/
/// @endcond
/**
* \defgroup ksz8051mnl_ethernet_phy_group PHY component (KSZ8051MNL)
*
* Driver for the ksz8051mnl component. This driver provides access to the main
* features of the PHY.
*
* \section dependencies Dependencies
* This driver depends on the following modules:
* - \ref gmac_group Ethernet Media Access Controller (GMAC) module.
*
* @{
*/
SPhyProps phyProps;
/* Max PHY number */
#define ETH_PHY_MAX_ADDR 31
/* Ethernet PHY operation max retry count */
#define ETH_PHY_RETRY_MAX 1000000
/* Ethernet PHY operation timeout */
#define ETH_PHY_TIMEOUT 10
/**
* \brief Find a valid PHY Address ( from addrStart to 31 ).
*
* \param p_gmac Pointer to the GMAC instance.
* \param uc_phy_addr PHY address.
* \param uc_start_addr Start address of the PHY to be searched.
*
* \return 0xFF when no valid PHY address is found.
*/
int ethernet_phy_addr = 0;
static uint8_t ethernet_phy_find_valid(Gmac *p_gmac, uint8_t uc_phy_addr,
uint8_t uc_start_addr)
{
uint32_t ul_value = 0;
uint8_t uc_cnt;
uint8_t uc_phy_address = uc_phy_addr;
gmac_enable_management(p_gmac, true);
/*
#define GMII_OUI_MSB 0x0022
#define GMII_OUI_LSB 0x05
PHYID1 = 0x0022
PHYID2 = 0x1550
0001_0101_0101_0000 = 0x1550 <= mask should be 0xFFF0
*/
/* Check the current PHY address */
gmac_phy_read(p_gmac, uc_phy_addr, GMII_PHYID1, &ul_value);
/* Find another one */
if (ul_value != GMII_OUI_MSB) {
ethernet_phy_addr = 0xFF;
for (uc_cnt = uc_start_addr; uc_cnt <= ETH_PHY_MAX_ADDR; uc_cnt++) {
uc_phy_address = (uc_phy_address + 1) & 0x1F;
ul_value = 0;
gmac_phy_read(p_gmac, uc_phy_address, GMII_PHYID1, &ul_value);
if (ul_value == GMII_OUI_MSB) {
ethernet_phy_addr = uc_phy_address;
break;
}
}
}
gmac_enable_management(p_gmac, false);
if (ethernet_phy_addr != 0xFF) {
gmac_phy_read(p_gmac, uc_phy_address, GMII_BMSR, &ul_value);
}
return ethernet_phy_addr;
}
/**
* \brief Perform a HW initialization to the PHY and set up clocks.
*
* This should be called only once to initialize the PHY pre-settings.
* The PHY address is the reset status of CRS, RXD[3:0] (the emacPins' pullups).
* The COL pin is used to select MII mode on reset (pulled up for Reduced MII).
* The RXDV pin is used to select test mode on reset (pulled up for test mode).
* The above pins should be predefined for corresponding settings in resetPins.
* The GMAC peripheral pins are configured after the reset is done.
*
* \param p_gmac Pointer to the GMAC instance.
* \param uc_phy_addr PHY address.
* \param ul_mck GMAC MCK.
*
* Return GMAC_OK if successfully, GMAC_TIMEOUT if timeout.
*/
uint8_t ethernet_phy_init(Gmac *p_gmac, uint8_t uc_phy_addr, uint32_t mck)
{
uint8_t uc_rc = GMAC_TIMEOUT;
uint8_t uc_phy;
ethernet_phy_reset(GMAC,uc_phy_addr);
/* Configure GMAC runtime clock */
uc_rc = gmac_set_mdc_clock(p_gmac, mck);
if (uc_rc != GMAC_OK) {
return 0;
}
/* Check PHY Address */
uc_phy = ethernet_phy_find_valid(p_gmac, uc_phy_addr, 0);
if (uc_phy == 0xFF) {
return 0;
}
if (uc_phy != uc_phy_addr) {
ethernet_phy_reset(p_gmac, uc_phy_addr);
}
phy_props.phy_chn = uc_phy;
return uc_phy;
}
/**
* \brief Get the Link & speed settings, and automatically set up the GMAC with the
* settings.
*
* \param p_gmac Pointer to the GMAC instance.
* \param uc_phy_addr PHY address.
* \param uc_apply_setting_flag Set to 0 to not apply the PHY configurations, else to apply.
*
* Return GMAC_OK if successfully, GMAC_TIMEOUT if timeout.
*/
uint8_t ethernet_phy_set_link(Gmac *p_gmac, uint8_t uc_phy_addr,
uint8_t uc_apply_setting_flag)
{
uint32_t ul_stat1;
uint32_t ul_stat2;
uint8_t uc_phy_address, uc_speed = true, uc_fd = true;
uint8_t uc_rc = GMAC_TIMEOUT;
gmac_enable_management(p_gmac, true);
uc_phy_address = uc_phy_addr;
uc_rc = gmac_phy_read(p_gmac, uc_phy_address, GMII_BMSR, &ul_stat1);
if (uc_rc != GMAC_OK) {
/* Disable PHY management and start the GMAC transfer */
gmac_enable_management(p_gmac, false);
return uc_rc;
}
if ((ul_stat1 & GMII_LINK_STATUS) == 0) {
/* Disable PHY management and start the GMAC transfer */
gmac_enable_management(p_gmac, false);
return GMAC_INVALID;
}
if (uc_apply_setting_flag == 0) {
/* Disable PHY management and start the GMAC transfer */
gmac_enable_management(p_gmac, false);
return uc_rc;
}
/* Read advertisement */
uc_rc = gmac_phy_read(p_gmac, uc_phy_address, GMII_ANAR, &ul_stat2);
phy_props.phy_stat1 = ul_stat1;
phy_props.phy_stat2 = ul_stat2;
if (uc_rc != GMAC_OK) {
/* Disable PHY management and start the GMAC transfer */
gmac_enable_management(p_gmac, false);
return uc_rc;
}
if ((ul_stat1 & GMII_100BASE_TX_FD) && (ul_stat2 & GMII_100TX_FDX)) {
/* Set GMAC for 100BaseTX and Full Duplex */
uc_speed = true;
uc_fd = true;
} else
if ((ul_stat1 & GMII_100BASE_T4_HD) && (ul_stat2 & GMII_100TX_HDX)) {
/* Set MII for 100BaseTX and Half Duplex */
uc_speed = true;
uc_fd = false;
} else
if ((ul_stat1 & GMII_10BASE_T_FD) && (ul_stat2 & GMII_10_FDX)) {
/* Set MII for 10BaseT and Full Duplex */
uc_speed = false;
uc_fd = true;
} else
if ((ul_stat1 & GMII_10BASE_T_HD) && (ul_stat2 & GMII_10_HDX)) {
/* Set MII for 10BaseT and Half Duplex */
uc_speed = false;
uc_fd = false;
}
gmac_set_speed(p_gmac, uc_speed);
gmac_enable_full_duplex(p_gmac, uc_fd);
/* Start the GMAC transfers */
gmac_enable_management(p_gmac, false);
return uc_rc;
}
PhyProps_t phy_props;
/**
* \brief Issue an auto negotiation of the PHY.
*
* \param p_gmac Pointer to the GMAC instance.
* \param uc_phy_addr PHY address.
*
* Return GMAC_OK if successfully, GMAC_TIMEOUT if timeout.
*/
uint8_t ethernet_phy_auto_negotiate(Gmac *p_gmac, uint8_t uc_phy_addr)
{
uint32_t ul_retry_max = ETH_PHY_RETRY_MAX;
uint32_t ul_value;
uint32_t ul_phy_anar;
uint32_t ul_retry_count = 0;
uint8_t uc_speed = 0;
uint8_t uc_fd=0;
uint8_t uc_rc = GMAC_TIMEOUT;
gmac_enable_management(p_gmac, true);
/* Set up control register */
uc_rc = gmac_phy_read(p_gmac, uc_phy_addr, GMII_BMCR, &ul_value);
if (uc_rc != GMAC_OK) {
gmac_enable_management(p_gmac, false);
phy_props.phy_result = -1;
return uc_rc;
}
ul_value &= ~(uint32_t)GMII_AUTONEG; /* Remove auto-negotiation enable */
ul_value &= ~(uint32_t)(GMII_LOOPBACK | GMII_POWER_DOWN);
ul_value |= (uint32_t)GMII_ISOLATE; /* Electrically isolate PHY */
uc_rc = gmac_phy_write(p_gmac, uc_phy_addr, GMII_BMCR, ul_value);
if (uc_rc != GMAC_OK) {
gmac_enable_management(p_gmac, false);
phy_props.phy_result = -2;
return uc_rc;
}
/*
* Set the Auto_negotiation Advertisement Register.
* MII advertising for Next page.
* 100BaseTxFD and HD, 10BaseTFD and HD, IEEE 802.3.
*/
ul_phy_anar = GMII_100TX_FDX | GMII_100TX_HDX | GMII_10_FDX | GMII_10_HDX |
GMII_AN_IEEE_802_3;
uc_rc = gmac_phy_write(p_gmac, uc_phy_addr, GMII_ANAR, ul_phy_anar);
if (uc_rc != GMAC_OK) {
gmac_enable_management(p_gmac, false);
phy_props.phy_result = -3;
return uc_rc;
}
/* Read & modify control register */
uc_rc = gmac_phy_read(p_gmac, uc_phy_addr, GMII_BMCR, &ul_value);
if (uc_rc != GMAC_OK) {
gmac_enable_management(p_gmac, false);
phy_props.phy_result = -4;
return uc_rc;
}
ul_value |= GMII_SPEED_SELECT | GMII_AUTONEG | GMII_DUPLEX_MODE;
uc_rc = gmac_phy_write(p_gmac, uc_phy_addr, GMII_BMCR, ul_value);
if (uc_rc != GMAC_OK) {
gmac_enable_management(p_gmac, false);
phy_props.phy_result = -5;
return uc_rc;
}
/* Restart auto negotiation */
ul_value |= (uint32_t)GMII_RESTART_AUTONEG;
ul_value &= ~(uint32_t)GMII_ISOLATE;
uc_rc = gmac_phy_write(p_gmac, uc_phy_addr, GMII_BMCR, ul_value);
if (uc_rc != GMAC_OK) {
gmac_enable_management(p_gmac, false);
phy_props.phy_result = -6;
return uc_rc;
}
/* Check if auto negotiation is completed */
while (1) {
uc_rc = gmac_phy_read(p_gmac, uc_phy_addr, GMII_BMSR, &ul_value);
if (uc_rc != GMAC_OK) {
gmac_enable_management(p_gmac, false);
phy_props.phy_result = -7;
return uc_rc;
}
/* Done successfully */
if (ul_value & GMII_AUTONEG_COMP) {
break;
}
/* Timeout check */
if (ul_retry_max) {
if (++ul_retry_count >= ul_retry_max) {
gmac_enable_management(p_gmac, false);
phy_props.phy_result = -8;
return GMAC_TIMEOUT;
}
}
}
/* Get the auto negotiate link partner base page */
uc_rc = gmac_phy_read(p_gmac, uc_phy_addr, GMII_PCR1, &phy_props.phy_params);
if (uc_rc != GMAC_OK) {
gmac_enable_management(p_gmac, false);
phy_props.phy_result = -9;
return uc_rc;
}
/* Set up the GMAC link speed */
if ((ul_phy_anar & phy_props.phy_params) & GMII_100TX_FDX) {
/* Set MII for 100BaseTX and Full Duplex */
uc_speed = true;
uc_fd = true;
} else if ((ul_phy_anar & phy_props.phy_params) & GMII_10_FDX) {
/* Set MII for 10BaseT and Full Duplex */
uc_speed = false;
uc_fd = true;
} else if ((ul_phy_anar & phy_props.phy_params) & GMII_100TX_HDX) {
/* Set MII for 100BaseTX and half Duplex */
uc_speed = true;
uc_fd = false;
} else if ((ul_phy_anar & phy_props.phy_params) & GMII_10_HDX) {
/* Set MII for 10BaseT and half Duplex */
uc_speed = false;
uc_fd = false;
}
gmac_set_speed(p_gmac, uc_speed);
gmac_enable_full_duplex(p_gmac, uc_fd);
/* Select Media Independent Interface type */
gmac_select_mii_mode(p_gmac, ETH_PHY_MODE);
gmac_enable_transmit(GMAC, true);
gmac_enable_receive(GMAC, true);
gmac_enable_management(p_gmac, false);
phy_props.phy_result = 1;
return uc_rc;
}
/**
* \brief Issue a SW reset to reset all registers of the PHY.
*
* \param p_gmac Pointer to the GMAC instance.
* \param uc_phy_addr PHY address.
*
* \Return GMAC_OK if successfully, GMAC_TIMEOUT if timeout.
*/
uint8_t ethernet_phy_reset(Gmac *p_gmac, uint8_t uc_phy_addr)
{
uint32_t ul_bmcr = GMII_RESET;
uint8_t uc_phy_address = uc_phy_addr;
uint32_t ul_timeout = ETH_PHY_TIMEOUT;
uint8_t uc_rc = GMAC_TIMEOUT;
gmac_enable_management(p_gmac, true);
ul_bmcr = GMII_RESET;
gmac_phy_write(p_gmac, uc_phy_address, GMII_BMCR, ul_bmcr);
do {
gmac_phy_read(p_gmac, uc_phy_address, GMII_BMCR, &ul_bmcr);
ul_timeout--;
} while ((ul_bmcr & GMII_RESET) && ul_timeout);
gmac_enable_management(p_gmac, false);
if (!ul_timeout) {
uc_rc = GMAC_OK;
}
return (uc_rc);
}
/// @cond 0
/**INDENT-OFF**/
#ifdef __cplusplus
}
#endif
/**INDENT-ON**/
/// @endcond
/**
* \}
*/