/* Copyright (c) 2015 Broadcom Corporation All Rights Reserved <:label-BRCM:2015:DUAL/GPL:standard This program is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License, version 2, as published by the Free Software Foundation (the "GPL"). 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. A copy of the GPL is available at http://www.broadcom.com/licenses/GPLv2.php, or by writing to the Free Software Foundation, Inc., 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA. :> */ /* * Created on: Dec 2015 * Author: yuval.raviv@broadcom.com */ /* * Phy driver for 6848 internal dual 100M phy */ #include "bus_drv.h" #include "phy_drv.h" #include "phy_drv_mii.h" #include "phy_drv_brcm.h" #include "rdp_map.h" #include "access_macros.h" static uint32_t enabled_ports; static int _phy_afe(phy_dev_t *phy_dev) { int ret; if ((ret = brcm_shadow_write(phy_dev, 2, 0x1a, 0x3be0))) /* Set internal and external current trim values */ goto Exit; if ((ret = brcm_shadow_write(phy_dev, 3, 0x23, 0x0006))) /* Cal reset */ goto Exit; if ((ret = brcm_shadow_write(phy_dev, 3, 0x23, 0x0000))) /* Cal reset disable */ goto Exit; if ((ret = brcm_shadow_write(phy_dev, 3, 0x07, 0x0002))) /* PCS Test Reg */ goto Exit; Exit: return ret; } static int _phy_init(phy_dev_t *phy_dev) { int ret; uint16_t val; if ((ret = mii_init(phy_dev))) goto Exit; /* LED Control: set LEDs to blinky link mode */ val = 0; val |= (1 << 3); /* Set LED0 to mode blinky link mode */ val |= (1 << 7); /* Set LED1 to mode blinky link mode */ if ((ret = brcm_shadow_write(phy_dev, 2, 0x15, val))) goto Exit; /* Enable force auto MDIX */ if ((ret = brcm_shadow_read(phy_dev, 1, 0x10, &val))) goto Exit; if ((ret = brcm_shadow_write(phy_dev, 1, 0x10, val | (1 << 14)))) goto Exit; /* AFE workaround */ if ((ret = _phy_afe(phy_dev))) goto Exit; Exit: return ret; } static int _phy_cfg(uint32_t port_map) { uint32_t data; /* RESET_N --> 1 */ READ_32(EGPHY_EPHY_RESET_CNTRL, data); data |= 0x10; WRITE_32(EGPHY_EPHY_RESET_CNTRL, data); udelay(50); /* DLLBYP_PIN_F --> 1 */ data = 0x02; WRITE_32(EGPHY_EPHY_TEST_CNTRL, data); udelay(50); /* RESET_N --> 0 */ READ_32(EGPHY_EPHY_RESET_CNTRL, data); data &= ~0x10; WRITE_32(EGPHY_EPHY_RESET_CNTRL, data); udelay(50); /* DLLBYP_PIN_F --> 1 */ data = 0x02; WRITE_32(EGPHY_EPHY_TEST_CNTRL, data); udelay(50); /* RESET_N_PHY_(0-3), RESET_N --> 1 */ data |= 0x1f; WRITE_32(EGPHY_EPHY_RESET_CNTRL, data); udelay(50); /* RESET_N_PHY_(0-3), RESET_N --> 0 */ data = 0x00; WRITE_32(EGPHY_EPHY_RESET_CNTRL, data); udelay(50); /* EGPHY_EPHY_PWR_MGNT */ data = 0X21fffffd; WRITE_32(EGPHY_EPHY_PWR_MGNT, data); udelay(50); if (port_map & 0x01) /* port 0 */ data &= ~(0x1f << 20); /* EXT_PWR_DOWN_PHY_0 */ if (port_map & 0x02) /* port 1 */ data &= ~(0x1f << 15); /* EXT_PWR_DOWN_PHY_1 */ if (port_map & 0x04) /* port 2 */ data &= ~(0x1f << 10); /* EXT_PWR_DOWN_PHY_2 */ if (port_map & 0x08) /* port 3 */ data &= ~(0x1f << 5); /* EXT_PWR_DOWN_PHY_3 */ if (port_map) data &= ~0x2000001c; /* IDDQ_GLOBAL_PWR, EXT_PWR_DOWN_BIAS, EXT_PWR_DOWN_DLL, EXT_PWR_DOWN_PHY */ WRITE_32(EGPHY_EPHY_PWR_MGNT, data); udelay(50); /* RESET_N --> 1 */ READ_32(EGPHY_EPHY_RESET_CNTRL, data); data |= 0x10; WRITE_32(EGPHY_EPHY_RESET_CNTRL, data); udelay(50); /* RESET_N --> 0 */ data = 0x00; WRITE_32(EGPHY_EPHY_RESET_CNTRL, data); udelay(50); return 0; } static int _phy_dev_add(phy_dev_t *phy_dev) { uint32_t port = (uint32_t)phy_dev->priv; enabled_ports |= (1 << port); return 0; } static int _phy_dev_del(phy_dev_t *phy_dev) { uint32_t port = (uint32_t)phy_dev->priv; enabled_ports &= ~(1 << port); return 0; } static int _phy_drv_init(phy_drv_t *phy_drv) { if (_phy_cfg(enabled_ports & 0xf)) { printk("Failed to initialize the ephy driver\n"); return -1; } phy_drv->initialized = 1; return 0; } #ifndef _CFE_ #define SP100_CARRIER_ERROR_MASK ((1<<9)|(1<<8)|(1<<5)) static int _phy_workaround_check(phy_dev_t *phy_dev) { uint16_t val; /* Read the auxiliary status summary register */ if ((phy_dev_read(phy_dev, 0x19, &val))) goto Error; /* Ensure the link is still up and speed is still 100M */ if (!((val >> 2) & 0x1) || !((val >> 3) & 0x1)) return 0; /* Read the receive packet counter register */ if (brcm_shadow_read(phy_dev, 3, 0x12, &val)) goto Error; /* If packets were received, the phy is working normally */ if (val) return 0; /* Read the auxiliary status register */ if (phy_dev_read(phy_dev, 0x11, &val)) goto Error; /* If a false carrier sense was detected, reset the phy */ if ((val & SP100_CARRIER_ERROR_MASK) == SP100_CARRIER_ERROR_MASK) { printk ("**** Detected EPHY unusual status, reset PHY to recover ****\n"); phy_dev_init(phy_dev); return 0; } /* Packets were not received yet nor a false carrier sense was detected, keep polling */ return 1; Error: printk ("_phy_workaround_check: Error accessing phy register\n"); return 0; } static void _phy_work_handler(phy_dev_t *phy_dev) { int ret; uint16_t val; /* Enable and reset RX packet counter */ val = 0; val |= (1 << 0); /* Packet Check Enable */ val |= (1 << 1); /* Receive Packet Counter Clear */ if ((ret = brcm_shadow_write(phy_dev, 3, 0x11, val))) goto Error; /* Clear RX packet counter by reading it */ if ((ret = brcm_shadow_read(phy_dev, 3, 0x12, &val))) goto Error; /* Clear error detected bits in the auxiliary status register by reading it */ if ((ret = phy_dev_read(phy_dev, 0x11, &val))) goto Error; /* Poll the phy until packets received or a reset was done to fix a false carrier sense problem */ while (_phy_workaround_check(phy_dev)) udelay(1000000); return; Error: printk ("_phy_work_handler: Error accessing phy register\n"); return; } #endif static int _phy_read_status(phy_dev_t *phy_dev) { int ret; #ifndef _CFE_ phy_speed_t speed = phy_dev->speed; #endif if ((ret = brcm_read_status(phy_dev))) goto Exit; #ifndef _CFE_ if (phy_dev->link && phy_dev->speed != speed && phy_dev->speed == PHY_SPEED_100) ret = phy_dev_queue_work(phy_dev, _phy_work_handler); #endif Exit: return ret; } static int _phy_power_set(phy_dev_t *phy_dev, int enable) { uint32_t data; uint32_t port = (uint32_t)phy_dev->priv; READ_32(EGPHY_EPHY_PWR_MGNT, data); if(enable) data &= ~(0x1 << (0x1c - port)); else data |= (0x1 << (0x1c - port)); WRITE_32(EGPHY_EPHY_PWR_MGNT, data); udelay(50); return 0; } phy_drv_t phy_drv_6848_ephy = { .phy_type = PHY_TYPE_6848_EPHY, .name = "EPHY", .power_set = _phy_power_set, .apd_set = brcm_ephy_apd_set, .eee_get = brcm_ephy_eee_get, .eee_set = brcm_ephy_eee_set, .read_status = _phy_read_status, .speed_set = mii_speed_set, .caps_get = mii_caps_get, .caps_set = mii_caps_set, .phyid_get = mii_phyid_get, .init = _phy_init, .dev_add = _phy_dev_add, .dev_del = _phy_dev_del, .drv_init = _phy_drv_init, };