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|
/*
* Copyright 2009-2011 Freescale Semiconductor, Inc.
* Author: Srikanth Srinivasan <srikanth.srinivasan@freescale.com>
*
* See file CREDITS for list of people who contributed to this
* project.
*
* This program is free software; you can redistribute it and/or
* modify it under the terms of the GNU General Public License as
* published by the Free Software Foundation; either version 2 of
* the License, or (at your option) any later version.
*
* This program is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with this program; if not, write to the Free Software
* Foundation, Inc., 59 Temple Place, Suite 330, Boston,
* MA 02111-1307 USA
*/
/*
* This file handles the board muxing between the Fman Ethernet MACs and
* the RGMII/SGMII/XGMII PHYs on a Freescale P5040 "Super Hydra" reference
* board. The RGMII PHYs are the two on-board 1Gb ports. The SGMII PHYs are
* provided by the standard Freescale four-port SGMII riser card. The 10Gb
* XGMII PHYs are provided via the XAUI riser card. The P5040 has 2 FMans
* and 5 1G interfaces and 10G interface per FMan. Based on the options in
* the RCW, we could have upto 3 SGMII cards and 1 XAUI card at a time.
*
* Muxing is handled via the PIXIS BRDCFG1 register. The EMI1 bits control
* muxing among the RGMII PHYs and the SGMII PHYs. The value for RGMII is
* always the same (0). The value for SGMII depends on which slot the riser is
* inserted in. The EMI2 bits control muxing for the the XGMII. Like SGMII,
* the value is based on which slot the XAUI is inserted in.
*
* The SERDES configuration is used to determine where the SGMII and XAUI cards
* exist, and also which Fman's MACs are routed to which PHYs. So for a given
* Fman MAC, there is one and only PHY it connects to. MACs cannot be routed
* to PHYs dynamically.
*
*
* This file also updates the device tree in three ways:
*
* 1) The status of each virtual MDIO node that is referenced by an Ethernet
* node is set to "okay".
*
* 2) The phy-handle property of each active Ethernet MAC node is set to the
* appropriate PHY node.
*
* 3) The "mux value" for each virtual MDIO node is set to the correct value,
* if necessary. Some virtual MDIO nodes do not have configurable mux
* values, so those values are hard-coded in the DTS. On the HYDRA board,
* the virtual MDIO node for the SGMII card needs to be updated.
*
* For all this to work, the device tree needs to have the following:
*
* 1) An alias for each PHY node that an Ethernet node could be routed to.
*
* 2) An alias for each real and virtual MDIO node that is disabled by default
* and might need to be enabled, and also might need to have its mux-value
* updated.
*/
#include <common.h>
#include <netdev.h>
#include <asm/fsl_serdes.h>
#include <fm_eth.h>
#include <fsl_mdio.h>
#include <malloc.h>
#include <fdt_support.h>
#include <asm/fsl_dtsec.h>
#include "../common/ngpixis.h"
#include "../common/fman.h"
#ifdef CONFIG_FMAN_ENET
#define BRDCFG1_EMI1_SEL_MASK 0x70
#define BRDCFG1_EMI1_SEL_SLOT1 0x10
#define BRDCFG1_EMI1_SEL_SLOT2 0x20
#define BRDCFG1_EMI1_SEL_SLOT5 0x30
#define BRDCFG1_EMI1_SEL_SLOT6 0x40
#define BRDCFG1_EMI1_SEL_SLOT7 0x50
#define BRDCFG1_EMI1_SEL_SLOT3 0x60
#define BRDCFG1_EMI1_SEL_RGMII 0x00
#define BRDCFG1_EMI1_EN 0x08
#define BRDCFG1_EMI2_SEL_MASK 0x06
#define BRDCFG1_EMI2_SEL_SLOT1 0x00
#define BRDCFG1_EMI2_SEL_SLOT2 0x02
#define BRDCFG2_REG_GPIO_SEL 0x20
/*
* BRDCFG1 mask and value for each MAC
*
* This array contains the BRDCFG1 values (in mask/val format) that route the
* MDIO bus to a particular RGMII or SGMII PHY.
*/
static struct {
u8 mask;
u8 val;
} mdio_mux[NUM_FM_PORTS];
/*
* Mapping of all 18 SERDES lanes to board slots. A value of '0' here means
* that the mapping must be determined dynamically, or that the lane maps to
* something other than a board slot
*/
static u8 lane_to_slot[] = {
7, 7, 0, 0, 0, 0, 0, 0, 0, 0, 2, 2, 2, 2, 1, 1, 0, 0, 0, 0
};
/*
* Set the board muxing for a given MAC
*
* The MDIO layer calls this function every time it wants to talk to a PHY.
*/
void super_hydra_mux_mdio(u8 mask, u8 val)
{
clrsetbits_8(&pixis->brdcfg1, mask, val);
}
struct super_hydra_mdio {
u8 mask;
u8 val;
struct mii_dev *realbus;
};
static int super_hydra_mdio_read(struct mii_dev *bus, int addr, int devad,
int regnum)
{
struct super_hydra_mdio *priv = bus->priv;
super_hydra_mux_mdio(priv->mask, priv->val);
return priv->realbus->read(priv->realbus, addr, devad, regnum);
}
static int super_hydra_mdio_write(struct mii_dev *bus, int addr, int devad,
int regnum, u16 value)
{
struct super_hydra_mdio *priv = bus->priv;
super_hydra_mux_mdio(priv->mask, priv->val);
return priv->realbus->write(priv->realbus, addr, devad, regnum, value);
}
static int super_hydra_mdio_reset(struct mii_dev *bus)
{
struct super_hydra_mdio *priv = bus->priv;
return priv->realbus->reset(priv->realbus);
}
static void super_hydra_mdio_set_mux(char *name, u8 mask, u8 val)
{
struct mii_dev *bus = miiphy_get_dev_by_name(name);
struct super_hydra_mdio *priv = bus->priv;
priv->mask = mask;
priv->val = val;
}
static int super_hydra_mdio_init(char *realbusname, char *fakebusname)
{
struct super_hydra_mdio *hmdio;
struct mii_dev *bus = mdio_alloc();
if (!bus) {
printf("Failed to allocate Hydra MDIO bus\n");
return -1;
}
hmdio = malloc(sizeof(*hmdio));
if (!hmdio) {
printf("Failed to allocate Hydra private data\n");
free(bus);
return -1;
}
bus->read = super_hydra_mdio_read;
bus->write = super_hydra_mdio_write;
bus->reset = super_hydra_mdio_reset;
sprintf(bus->name, fakebusname);
hmdio->realbus = miiphy_get_dev_by_name(realbusname);
if (!hmdio->realbus) {
printf("No bus with name %s\n", realbusname);
free(bus);
free(hmdio);
return -1;
}
bus->priv = hmdio;
return mdio_register(bus);
}
/*
* Given the following ...
*
* 1) A pointer to an Fman Ethernet node (as identified by the 'compat'
* compatible string and 'addr' physical address)
*
* 2) An Fman port
*
* ... update the phy-handle property of the Ethernet node to point to the
* right PHY. This assumes that we already know the PHY for each port. That
* information is stored in mdio_mux[].
*
* The offset of the Fman Ethernet node is also passed in for convenience, but
* it is not used.
*
* Note that what we call "Fman ports" (enum fm_port) is really an Fman MAC.
* Inside the Fman, "ports" are things that connect to MACs. We only call them
* ports in U-Boot because on previous Ethernet devices (e.g. Gianfar), MACs
* and ports are the same thing.
*/
void board_ft_fman_fixup_port(void *fdt, char *compat, phys_addr_t addr,
enum fm_port port, int offset)
{
enum srds_prtcl device;
int lane, slot, phy;
char alias[32];
/* RGMII and XGMII are already mapped correctly in the DTS */
if (fm_info_get_enet_if(port) == PHY_INTERFACE_MODE_SGMII) {
device = serdes_device_from_fm_port(port);
lane = serdes_get_first_lane(device);
slot = lane_to_slot[lane];
phy = fm_info_get_phy_address(port);
sprintf(alias, "phy_sgmii_slot%u_%x", slot, phy);
fdt_set_phy_handle(fdt, compat, addr, alias);
}
}
#define PIXIS_SW2_LANE_23_SEL 0x80
#define PIXIS_SW2_LANE_45_SEL 0x40
#define PIXIS_SW2_LANE_67_SEL_MASK 0x30
#define PIXIS_SW2_LANE_67_SEL_5 0x00
#define PIXIS_SW2_LANE_67_SEL_6 0x20
#define PIXIS_SW2_LANE_67_SEL_7 0x10
#define PIXIS_SW2_LANE_8_SEL 0x08
#define PIXIS_SW2_LANE_1617_SEL 0x04
#define PIXIS_SW11_LANE_9_SEL 0x04
/*
* Initialize the lane_to_slot[] array.
*
* On the P4080DS "Expedition" board, the mapping of SERDES lanes to board
* slots is hard-coded. On the Hydra board, however, the mapping is controlled
* by board switch SW2, so the lane_to_slot[] array needs to be dynamically
* initialized.
*/
static void initialize_lane_to_slot(void)
{
u8 sw2 = in_8(&PIXIS_SW(2));
/* SW11 appears in the programming model as SW9 */
u8 sw11 = in_8(&PIXIS_SW(9));
lane_to_slot[2] = (sw2 & PIXIS_SW2_LANE_23_SEL) ? 7 : 4;
lane_to_slot[3] = lane_to_slot[2];
lane_to_slot[4] = (sw2 & PIXIS_SW2_LANE_45_SEL) ? 7 : 6;
lane_to_slot[5] = lane_to_slot[4];
switch (sw2 & PIXIS_SW2_LANE_67_SEL_MASK) {
case PIXIS_SW2_LANE_67_SEL_5:
lane_to_slot[6] = 5;
break;
case PIXIS_SW2_LANE_67_SEL_6:
lane_to_slot[6] = 6;
break;
case PIXIS_SW2_LANE_67_SEL_7:
lane_to_slot[6] = 7;
break;
}
lane_to_slot[7] = lane_to_slot[6];
lane_to_slot[8] = (sw2 & PIXIS_SW2_LANE_8_SEL) ? 3 : 0;
lane_to_slot[9] = (sw11 & PIXIS_SW11_LANE_9_SEL) ? 0 : 3;
lane_to_slot[16] = (sw2 & PIXIS_SW2_LANE_1617_SEL) ? 1 : 0;
lane_to_slot[17] = lane_to_slot[16];
}
#endif /* #ifdef CONFIG_FMAN_ENET */
/*
* Configure the status for the virtual MDIO nodes
*
* Rather than create the virtual MDIO nodes from scratch for each active
* virtual MDIO, we expect the DTS to have the nodes defined already, and we
* only enable the ones that are actually active.
*
* We assume that the DTS already hard-codes the status for all the
* virtual MDIO nodes to "disabled", so all we need to do is enable the
* active ones.
*/
void fdt_fixup_board_enet(void *fdt)
{
#ifdef CONFIG_FMAN_ENET
enum fm_port i;
int lane, slot;
for (i = FM1_DTSEC1; i < FM1_DTSEC1 + CONFIG_SYS_NUM_FM1_DTSEC; i++) {
int idx = i - FM1_DTSEC1;
switch (fm_info_get_enet_if(i)) {
case PHY_INTERFACE_MODE_SGMII:
lane = serdes_get_first_lane(SGMII_FM1_DTSEC1 + idx);
if (lane >= 0) {
char alias[32];
slot = lane_to_slot[lane];
sprintf(alias, "hydra_sg_slot%u", slot);
fdt_status_okay_by_alias(fdt, alias);
debug("Enabled MDIO node %s (slot %i)\n",
alias, slot);
}
break;
case PHY_INTERFACE_MODE_RGMII:
fdt_status_okay_by_alias(fdt, "hydra_rg");
debug("Enabled MDIO node hydra_rg\n");
break;
default:
break;
}
}
lane = serdes_get_first_lane(XAUI_FM1);
if (lane >= 0) {
char alias[32];
slot = lane_to_slot[lane];
sprintf(alias, "hydra_xg_slot%u", slot);
fdt_status_okay_by_alias(fdt, alias);
debug("Enabled MDIO node %s (slot %i)\n", alias, slot);
}
#if CONFIG_SYS_NUM_FMAN == 2
for (i = FM2_DTSEC1; i < FM2_DTSEC1 + CONFIG_SYS_NUM_FM2_DTSEC; i++) {
int idx = i - FM2_DTSEC1;
switch (fm_info_get_enet_if(i)) {
case PHY_INTERFACE_MODE_SGMII:
lane = serdes_get_first_lane(SGMII_FM2_DTSEC1 + idx);
if (lane >= 0) {
char alias[32];
slot = lane_to_slot[lane];
sprintf(alias, "hydra_sg_slot%u", slot);
fdt_status_okay_by_alias(fdt, alias);
debug("Enabled MDIO node %s (slot %i)\n",
alias, slot);
}
break;
case PHY_INTERFACE_MODE_RGMII:
fdt_status_okay_by_alias(fdt, "hydra_rg");
debug("Enabled MDIO node hydra_rg\n");
break;
default:
break;
}
}
lane = serdes_get_first_lane(XAUI_FM2);
if (lane >= 0) {
char alias[32];
slot = lane_to_slot[lane];
sprintf(alias, "hydra_xg_slot%u", slot);
fdt_status_okay_by_alias(fdt, alias);
debug("Enabled MDIO node %s (slot %i)\n", alias, slot);
}
#endif /* CONFIG_SYS_NUM_FMAN == 2 */
#endif /* CONFIG_FMAN_ENET */
}
/*
* Mapping of SerDes Protocol to MDIO MUX value and PHY address.
*
* Fman 1:
* DTSEC1 | DTSEC2 | DTSEC3 | DTSEC4
* Mux Phy | Mux Phy | Mux Phy | Mux Phy
* Value Addr | Value Addr | Value Addr | Value Addr
* 0x00 2 1c | 2 1d | 2 1e | 2 1f
* 0x01 | | 6 1c |
* 0x02 | | 3 1c | 3 1d
* 0x03 2 1c | 2 1d | 2 1e | 2 1f
* 0x04 2 1c | 2 1d | 2 1e | 2 1f
* 0x05 | | 3 1c | 3 1d
* 0x06 2 1c | 2 1d | 2 1e | 2 1f
* 0x07 | | 6 1c |
* 0x11 2 1c | 2 1d | 2 1e | 2 1f
* 0x2a 2 | | 2 1e | 2 1f
* 0x34 6 1c | 6 1d | 4 1e | 4 1f
* 0x35 | | 3 1c | 3 1d
* 0x36 6 1c | 6 1d | 4 1e | 4 1f
* | | |
* Fman 2: | | |
* DTSEC1 | DTSEC2 | DTSEC3 | DTSEC4
* EMI1 | EMI1 | EMI1 | EMI1
* Mux Phy | Mux Phy | Mux Phy | Mux Phy
* Value Addr | Value Addr | Value Addr | Value Addr
* 0x00 | | 6 1c | 6 1d
* 0x01 | | |
* 0x02 | | 6 1c | 6 1d
* 0x03 3 1c | 3 1d | 6 1c | 6 1d
* 0x04 3 1c | 3 1d | 6 1c | 6 1d
* 0x05 | | 6 1c | 6 1d
* 0x06 | | 6 1c | 6 1d
* 0x07 | | |
* 0x11 | | |
* 0x2a | | |
* 0x34 | | |
* 0x35 | | |
* 0x36 | | |
*/
int board_eth_init(bd_t *bis)
{
#ifdef CONFIG_FMAN_ENET
struct fsl_pq_mdio_info dtsec_mdio_info;
struct tgec_mdio_info tgec_mdio_info;
unsigned int i, slot;
int lane;
ccsr_gur_t *gur = (void *)(CONFIG_SYS_MPC85xx_GUTS_ADDR);
int srds_prtcl = (in_be32(&gur->rcwsr[4]) &
FSL_CORENET_RCWSR4_SRDS_PRTCL) >> 26;
printf("Initializing Fman\n");
initialize_lane_to_slot();
/* We want to use the PIXIS to configure MUX routing, not GPIOs. */
setbits_8(&pixis->brdcfg2, BRDCFG2_REG_GPIO_SEL);
memset(mdio_mux, 0, sizeof(mdio_mux));
dtsec_mdio_info.regs =
(struct tsec_mii_mng *)CONFIG_SYS_FM1_DTSEC1_MDIO_ADDR;
dtsec_mdio_info.name = DEFAULT_FM_MDIO_NAME;
/* Register the real 1G MDIO bus */
fsl_pq_mdio_init(bis, &dtsec_mdio_info);
tgec_mdio_info.regs =
(struct tgec_mdio_controller *)CONFIG_SYS_FM1_TGEC_MDIO_ADDR;
tgec_mdio_info.name = DEFAULT_FM_TGEC_MDIO_NAME;
/* Register the real 10G MDIO bus */
fm_tgec_mdio_init(bis, &tgec_mdio_info);
/* Register the three virtual MDIO front-ends */
super_hydra_mdio_init(DEFAULT_FM_MDIO_NAME,
"SUPER_HYDRA_RGMII_MDIO");
super_hydra_mdio_init(DEFAULT_FM_MDIO_NAME,
"SUPER_HYDRA_FM1_SGMII_MDIO");
super_hydra_mdio_init(DEFAULT_FM_MDIO_NAME,
"SUPER_HYDRA_FM2_SGMII_MDIO");
super_hydra_mdio_init(DEFAULT_FM_TGEC_MDIO_NAME,
"SUPER_HYDRA_FM1_TGEC_MDIO");
super_hydra_mdio_init(DEFAULT_FM_TGEC_MDIO_NAME,
"SUPER_HYDRA_FM2_TGEC_MDIO");
/*
* Program the DTSEC PHY addresses assuming that they are all SGMII.
* For any DTSEC that's RGMII, we'll override its PHY address later.
* We assume that DTSEC5 is only used for RGMII.
*/
fm_info_set_phy_address(FM1_DTSEC1, CONFIG_SYS_FM1_DTSEC1_PHY_ADDR);
fm_info_set_phy_address(FM1_DTSEC2, CONFIG_SYS_FM1_DTSEC2_PHY_ADDR);
fm_info_set_phy_address(FM1_10GEC1, CONFIG_SYS_FM2_10GEC1_PHY_ADDR);
#if (CONFIG_SYS_NUM_FMAN == 2)
fm_info_set_phy_address(FM2_DTSEC1, CONFIG_SYS_FM2_DTSEC1_PHY_ADDR);
fm_info_set_phy_address(FM2_DTSEC2, CONFIG_SYS_FM2_DTSEC2_PHY_ADDR);
fm_info_set_phy_address(FM2_DTSEC3, CONFIG_SYS_FM2_DTSEC1_PHY_ADDR);
fm_info_set_phy_address(FM2_DTSEC4, CONFIG_SYS_FM2_DTSEC2_PHY_ADDR);
fm_info_set_phy_address(FM2_10GEC1, CONFIG_SYS_FM1_10GEC1_PHY_ADDR);
#endif
switch (srds_prtcl) {
case 0:
case 3:
case 4:
case 6:
case 0x11:
case 0x2a:
case 0x34:
case 0x36:
fm_info_set_phy_address(FM1_DTSEC3,
CONFIG_SYS_FM1_DTSEC3_PHY_ADDR);
fm_info_set_phy_address(FM1_DTSEC4,
CONFIG_SYS_FM1_DTSEC4_PHY_ADDR);
break;
case 1:
case 2:
case 5:
case 7:
case 0x35:
fm_info_set_phy_address(FM1_DTSEC3,
CONFIG_SYS_FM1_DTSEC1_PHY_ADDR);
fm_info_set_phy_address(FM1_DTSEC4,
CONFIG_SYS_FM1_DTSEC2_PHY_ADDR);
break;
default:
printf("Fman: Unsupport SerDes Protocol 0x%02x\n", srds_prtcl);
break;
}
for (i = FM1_DTSEC1; i < FM1_DTSEC1 + CONFIG_SYS_NUM_FM1_DTSEC; i++) {
int idx = i - FM1_DTSEC1;
switch (fm_info_get_enet_if(i)) {
case PHY_INTERFACE_MODE_SGMII:
lane = serdes_get_first_lane(SGMII_FM1_DTSEC1 + idx);
if (lane < 0)
break;
slot = lane_to_slot[lane];
mdio_mux[i].mask = BRDCFG1_EMI1_SEL_MASK;
debug("FM1@DTSEC%u expects SGMII in slot %u\n",
idx + 1, slot);
switch (slot) {
case 1:
mdio_mux[i].val = BRDCFG1_EMI1_SEL_SLOT1 |
BRDCFG1_EMI1_EN;
break;
case 2:
mdio_mux[i].val = BRDCFG1_EMI1_SEL_SLOT2 |
BRDCFG1_EMI1_EN;
break;
case 3:
mdio_mux[i].val = BRDCFG1_EMI1_SEL_SLOT3 |
BRDCFG1_EMI1_EN;
break;
case 5:
mdio_mux[i].val = BRDCFG1_EMI1_SEL_SLOT5 |
BRDCFG1_EMI1_EN;
break;
case 6:
mdio_mux[i].val = BRDCFG1_EMI1_SEL_SLOT6 |
BRDCFG1_EMI1_EN;
break;
case 7:
mdio_mux[i].val = BRDCFG1_EMI1_SEL_SLOT7 |
BRDCFG1_EMI1_EN;
break;
};
super_hydra_mdio_set_mux("SUPER_HYDRA_FM1_SGMII_MDIO",
mdio_mux[i].mask, mdio_mux[i].val);
fm_info_set_mdio(i,
miiphy_get_dev_by_name("SUPER_HYDRA_FM1_SGMII_MDIO"));
break;
case PHY_INTERFACE_MODE_RGMII:
/*
* FM1 DTSEC5 is routed via EC1 to the first on-board
* RGMII port. FM2 DTSEC5 is routed via EC2 to the
* second on-board RGMII port. The other DTSECs cannot
* be routed to RGMII.
*/
debug("FM1@DTSEC%u is RGMII at address %u\n",
idx + 1, 0);
fm_info_set_phy_address(i, 0);
mdio_mux[i].mask = BRDCFG1_EMI1_SEL_MASK;
mdio_mux[i].val = BRDCFG1_EMI1_SEL_RGMII |
BRDCFG1_EMI1_EN;
super_hydra_mdio_set_mux("SUPER_HYDRA_RGMII_MDIO",
mdio_mux[i].mask, mdio_mux[i].val);
fm_info_set_mdio(i,
miiphy_get_dev_by_name("SUPER_HYDRA_RGMII_MDIO"));
break;
case PHY_INTERFACE_MODE_NONE:
fm_info_set_phy_address(i, 0);
break;
default:
printf("Fman1: DTSEC%u set to unknown interface %i\n",
idx + 1, fm_info_get_enet_if(i));
fm_info_set_phy_address(i, 0);
break;
}
}
/*
* For 10G, we only support one XAUI card per Fman. If present, then we
* force its routing and never touch those bits again, which removes the
* need for Linux to do any muxing. This works because of the way
* BRDCFG1 is defined, but it's a bit hackish.
*
* The PHY address for the XAUI card depends on which slot it's in. The
* macros we use imply that the PHY address is based on which FM, but
* that's not true. On the P4080DS, FM1 could only use XAUI in slot 5,
* and FM2 could only use a XAUI in slot 4. On the Hydra board, we
* check the actual slot and just use the macros as-is, even though
* the P3041 and P5020 only have one Fman.
*/
lane = serdes_get_first_lane(XAUI_FM1);
if (lane >= 0) {
debug("FM1@TGEC1 expects XAUI in slot %u\n", lane_to_slot[lane]);
mdio_mux[FM1_10GEC1].mask = BRDCFG1_EMI2_SEL_MASK;
mdio_mux[FM1_10GEC1].val = BRDCFG1_EMI2_SEL_SLOT2;
super_hydra_mdio_set_mux("SUPER_HYDRA_FM1_TGEC_MDIO",
mdio_mux[i].mask, mdio_mux[i].val);
}
fm_info_set_mdio(FM1_10GEC1,
miiphy_get_dev_by_name("SUPER_HYDRA_FM1_TGEC_MDIO"));
#if (CONFIG_SYS_NUM_FMAN == 2)
for (i = FM2_DTSEC1; i < FM2_DTSEC1 + CONFIG_SYS_NUM_FM2_DTSEC; i++) {
int idx = i - FM2_DTSEC1;
switch (fm_info_get_enet_if(i)) {
case PHY_INTERFACE_MODE_SGMII:
lane = serdes_get_first_lane(SGMII_FM2_DTSEC1 + idx);
if (lane < 0)
break;
slot = lane_to_slot[lane];
mdio_mux[i].mask = BRDCFG1_EMI1_SEL_MASK;
debug("FM2@DTSEC%u expects SGMII in slot %u\n",
idx + 1, slot);
switch (slot) {
case 1:
mdio_mux[i].val = BRDCFG1_EMI1_SEL_SLOT1 |
BRDCFG1_EMI1_EN;
break;
case 2:
mdio_mux[i].val = BRDCFG1_EMI1_SEL_SLOT2 |
BRDCFG1_EMI1_EN;
break;
case 3:
mdio_mux[i].val = BRDCFG1_EMI1_SEL_SLOT3 |
BRDCFG1_EMI1_EN;
break;
case 5:
mdio_mux[i].val = BRDCFG1_EMI1_SEL_SLOT5 |
BRDCFG1_EMI1_EN;
break;
case 6:
mdio_mux[i].val = BRDCFG1_EMI1_SEL_SLOT6 |
BRDCFG1_EMI1_EN;
break;
case 7:
mdio_mux[i].val = BRDCFG1_EMI1_SEL_SLOT7 |
BRDCFG1_EMI1_EN;
break;
};
super_hydra_mdio_set_mux("SUPER_HYDRA_FM2_SGMII_MDIO",
mdio_mux[i].mask, mdio_mux[i].val);
fm_info_set_mdio(i,
miiphy_get_dev_by_name("SUPER_HYDRA_FM2_SGMII_MDIO"));
break;
case PHY_INTERFACE_MODE_RGMII:
/*
* FM1 DTSEC5 is routed via EC1 to the first on-board
* RGMII port. FM2 DTSEC5 is routed via EC2 to the
* second on-board RGMII port. The other DTSECs cannot
* be routed to RGMII.
*/
debug("FM2@DTSEC%u is RGMII at address %u\n",
idx + 1, 1);
fm_info_set_phy_address(i, 1);
mdio_mux[i].mask = BRDCFG1_EMI1_SEL_MASK;
mdio_mux[i].val = BRDCFG1_EMI1_SEL_RGMII |
BRDCFG1_EMI1_EN;
super_hydra_mdio_set_mux("SUPER_HYDRA_RGMII_MDIO",
mdio_mux[i].mask, mdio_mux[i].val);
fm_info_set_mdio(i,
miiphy_get_dev_by_name("SUPER_HYDRA_RGMII_MDIO"));
break;
case PHY_INTERFACE_MODE_NONE:
fm_info_set_phy_address(i, 0);
break;
default:
printf("Fman2: DTSEC%u set to unknown interface %i\n",
idx + 1, fm_info_get_enet_if(i));
fm_info_set_phy_address(i, 0);
break;
}
}
/*
* For 10G, we only support one XAUI card per Fman. If present, then we
* force its routing and never touch those bits again, which removes the
* need for Linux to do any muxing. This works because of the way
* BRDCFG1 is defined, but it's a bit hackish.
*
* The PHY address for the XAUI card depends on which slot it's in. The
* macros we use imply that the PHY address is based on which FM, but
* that's not true. On the P4080DS, FM1 could only use XAUI in slot 5,
* and FM2 could only use a XAUI in slot 4. On the Hydra board, we
* check the actual slot and just use the macros as-is, even though
* the P3041 and P5020 only have one Fman.
*/
lane = serdes_get_first_lane(XAUI_FM2);
if (lane >= 0) {
debug("FM2@TGEC1 expects XAUI in slot %u\n", lane_to_slot[lane]);
mdio_mux[FM2_10GEC1].mask = BRDCFG1_EMI2_SEL_MASK;
mdio_mux[FM2_10GEC1].val = BRDCFG1_EMI2_SEL_SLOT1;
super_hydra_mdio_set_mux("SUPER_HYDRA_FM2_TGEC_MDIO",
mdio_mux[i].mask, mdio_mux[i].val);
}
fm_info_set_mdio(FM2_10GEC1,
miiphy_get_dev_by_name("SUPER_HYDRA_FM2_TGEC_MDIO"));
#endif
cpu_eth_init(bis);
#endif
return pci_eth_init(bis);
}
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